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A case study on decompounding in Indian language IR

Published online by Cambridge University Press:  03 June 2024

Siba Sankar Sahu*
Affiliation:
School of Computer Science Engineering and Technology, Bennett University, Greater Noida, Uttar Pradesh, India
Sukomal Pal
Affiliation:
Indian Institute of Technology (BHU), Department of Computer Science and Engineering, Varanasi, Uttar Pradesh, India
*
Corresponding author: Siba Sankar Sahu; Email: [email protected], [email protected]

Abstract

Decompounding is an essential preprocessing step in text-processing tasks such as machine translation, speech recognition, and information retrieval (IR). Here, the IR issues are explored from five viewpoints. (A) Does word decompounding impact the Indian language IR? If yes, to what extent? (B) Can corpus-based decompounding models be used in the Indian language IR? If yes, how? (C) Can machine learning and deep learning-based decompounding models be applied in the Indian language IR? If yes, how? (D) Among the different decompounding models (corpus-based, hybrid machine learning-based, and deep learning-based), which provides the best effectiveness in the IR domain? (E) Among the different IR models, which provides the best effectiveness from the IR perspective? This study proposes different corpus-based, hybrid machine learning-based, and deep learning-based decompounding models in Indian languages (Marathi, Hindi, and Sanskrit). Moreover, we evaluate the effectiveness of each activity from an IR perspective only. It is observed that the different decompounding models improve IR effectiveness. The deep learning-based decompounding models outperform the corpus-based and hybrid machine learning-based models in Indian language IR. Among the different deep learning-based models, the Bi-LSTM-A model performs best and improves mean average precision (MAP) by 28.02% in Marathi. Similarly, the Bi-RNN-A model improves MAP by 18.18% and 6.1% in Hindi and Sanskrit, respectively. Among the retrieval models, the In_expC2 model outperforms others in Marathi and Hindi, and the BB2 model outperforms others in Sanskrit.

Type
Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1. Introduction

In natural languages, compound words are formed by concatenating two or more words. Compound words create challenge for different natural language processing (NLP) applications like machine translation, text classification, speech recognition, and information retrieval (IR). In the IR domain, compound words generate a vocabulary mismatch between a query and the documents in the collection. For example, if a query comprises the term ‘book’, and the document includes ‘notebook’ it may be retrieved at a lower rank than the document consisting of ‘note’ and ‘book’. Hence, decompounding is an essential preprocessing step for compounding languages like German, Finnish, Dutch, and Bengali, where compound splitting improves the effectiveness of an IR system Braschler and Ripplinger (Reference Braschler and Ripplinger2004), Ganguly et al. (Reference Ganguly, Leveling and Jones2013). Although the effect of decompounding has been extensively studied in European languages, it is less explored in Indian languages like Marathi, Hindi, and Sanskrit. This study explores and evaluates the effect of decompounding in Indian languages IR.

The Indian language compound words are broadly categorised into two types. First is a typical compound word: a simple concatenation of two or more words. E.g., ‘note’ and ‘book’ are combined to form a ‘notebook’. Second is a sandhied compound word: according to sandhi rules, the tail constituent of the first component changes at the merging location (end of the first word and start of the second word). For example, ‘vidya’ and ‘alaya’ are combined to form ‘vidyalaya’. These modifications make splitting a sandhied compound word challenging in Indian languages. An additional feature of the Indian language compound word is that one of the compound constituents may not be used independently as a meaningful word. For example, in ‘upapradhanmantri’, ‘upa’ does not have independent use on its own but used as the prefix of another word. A predefined prefix list prevents the wrong splitting of compound words. We also noticed that splitting a compound word such as ‘underworld’ into ‘under’ and ‘world’ changes the original meaning of a compound word. Splitting of these compound words is syntactically correct but generates semantically unrelated meanings. Hence, we avoid semantically incorrect compound word splitting to improve the effectiveness of an IR system.

Different researchers proposed and evaluated different decompounding models such as corpus-based (Adda-Decker Reference Adda-Decker2003; Deepa et al. Reference Deepa, Bali, Ramakrishnan and Talukdar2004; Ganguly et al. Reference Ganguly, Leveling and Jones2013), machine learning based Ajees and Graham (Reference Ajees and Graham2018), and deep learning-based (Hellwig and Nehrdich Reference Hellwig and Nehrdich2018; Aralikatte et al. Reference Aralikatte, Gantayat, Panwar, Sankaran and Mani2018a; Hellwig Reference Hellwig2015) in Asian and European languages. Among the different decompounding models, they observed that the corpus-based decompounding models perform poorly in morphological-rich Indian languages. The primary reason is the inherent characteristics of Indian languages. The performance and drawback of the corpus-based decompounding model in Sanskrit are described in Bhardwaj et al. (Reference Bhardwaj, Gantayat, Chaturvedi, Garg and Agarwal2018). Different machine learning-based models improve effectiveness in morphologically rich languages. In recent years, the deep learning-based models outperform the corpus-based decompounding models in Sanskrit (Dave et al. Reference Dave, Singh, D. P. and Lall2021; Hellwig and Nehrdich Reference Hellwig and Nehrdich2018; Aralikatte et al. Reference Aralikatte, Gantayat, Panwar, Sankaran and Mani2018a; Hellwig Reference Hellwig2015).

To the best of our knowledge, no previous studies exist on the effect of decompounding models in Indian languages IR Koehn and Knight (Reference Koehn and Knight2003), Ajees and Graham (Reference Ajees and Graham2018), Aralikatte et al. (Reference Aralikatte, Gantayat, Panwar, Sankaran and Mani2018a). This study explores the impact of different decompounding models, i.e. corpus-based, hybrid machine learning-based, and deep learning-based in Indian language IR. The corpus-based model comprises dictionary-based approaches. The hybrid machine learning-based model consists of a dictionary and machine learning-based approaches. We also explore different deep learning-based models. We used the TerrierFootnote a retrieval system to evaluate decompounding models’ effectiveness in the IR domain.

Primarily, we investigated the following research questions (RQs).

  1. RQ1: Does word decompounding impact the Indian language IR? If yes, to what extent?

  2. RQ2: Can corpus-based decompounding models be used in the Indian language IR? If yes, how?

  3. RQ3: Can machine learning and deep learning-based decompounding models be applied in the Indian language IR? If yes, how?

  4. RQ4: Among the different decompounding models (corpus-based, hybrid machine learning-based, and deep learning-based), which provides the best effectiveness in the IR domain?

  5. RQ5: Among the different IR models, which provides the best effectiveness from the IR perspective?

Therefore, we proposed different decompounding models in Indian languages and evaluated their effectiveness in the IR domain. We also summarise the benefits and drawbacks of decompounding models in Indian languages. The contributions of this article can be summarised as follows.

  1. (1) We explore and evaluate three decompounding models: corpus-based, hybrid machine learning-based, and deep learning-based models in Indian languages.

  2. (2) We propose two novel decompounding models (machine learning and deep learning-based).

  3. (3) We evaluate the effectiveness of different decompounding models in different languages and compare them with the no decompounding approach in the IR domain.

  4. (4) Analysis has been done for different decompounding models and suggests the best for a language.

  5. (5) Analysis has been done for different IR models and suggests the best for a language.

The rest of the paper is organised as follows. Section 2 presents an overview of decompounding approaches in different languages. We elaborate on the problem statement in Section 3. Section 4 describes the decompounding approaches implemented in Indian languages. A brief explanation of different IR models is presented in Section 6. Section 7 describes the evaluation metrics used in the experimentation. The test collection statistic is presented in Section 8. The experimental setup is presented in Section 9 followed by the experimental results in Section 10. More insightful discussions have been summarised in Section 11. Finally, we conclude with future work in Section 12.

2. Background and related work

In a morphologically rich language, compound words are generated by concatenating two or more words, using sandhiFootnote b principles, or combining several morphemes using linking elements. Different compound words in a lexicon affect the performance of computational tasks like machine translation, information extraction, and creating OOV words in the dictionary. So, decompounding is an essential preprocessing step in the text analysis domain. Early literature suggests that the decompounding models primarily use basic ‘mechanical’ segmentation methods based on string matching. The most common practice in this approach is the dictionary-based method. Different machine learning-based decompounding models have been proposed in the last decade. These models use a feature engineering approach to perform the decompounding operation. In recent years, deep learning-based decompounding models have improved the effectiveness of different morphologically rich European and Asian languages. We formalised the state-of-the-art decompounding models in three subsections: corpus-based, machine-learning, and deep learning-based.

2.1 Corpus-based decompounding methods

Koehn and Knight (Reference Koehn and Knight2003) proposed a corpus-based decompounding model in German-English statistical machine translation. They used the geometric mean of word frequency to detect the splitting point location. They pointed out that decompounding algorithms improve the efficiency of machine translation. Leveling et al. (Reference Leveling, Magdy and Jones2011) investigated a corpus-based decompounding model in German-English cross-language patent retrieval. They noticed that the decompounding model reduces the OOV and improves the effectiveness of the IR system. Hollink et al. (Reference Hollink, Kamps, Monz and De Rijke2004) evaluated the effect of stemming, lemmatisation, and decompounding algorithms in eight European languages. They observed that the corpus-based decompounding model improves retrieval effectiveness in Dutch, Finnish, German, and Swedish languages. The decompounding algorithm improves an mean average precision (MAP) score of 4–18.7% in different morphologically rich European languages. Airio (Reference Airio2006) examined the impact of stemming, lemmatisation, and decompounding methods on monolingual and bilingual retrieval. They noticed that the decompounding algorithm does not improve effectiveness in English, Finnish, German, and Swedish monolingual retrieval. However, the decompounding method enhances effectiveness in English to Dutch, Finnish, German, and Swedish bilingual retrieval. Rigouts Terryn et al. (Reference Rigouts Terryn, Macken and Lefever2016) investigated the impact of a decompounding module on the Dutch hypernym detection. They observed that the decompounding module improves precision and recall.

Braschler and Ripplinger (Reference Braschler and Ripplinger2004) evaluated the effects of stemming and decompounding techniques in German IR. They found that stemming and careful decompounding enhance the effectiveness of IR systems. Alfonseca et al. (Reference Alfonseca, Bilac and Pharies2008) presented a language-independent decompounding method in German. They observed that the decompounding method improves precision, recall, and accuracy in morphologically complex European languages. Laureys et al. (Reference Laureys, Vandeghinste and Duchateau2002) evaluated the impact of the decompounding module in large vocabulary continuous speech recognition (LVCSR) in Dutch. The decompound module combines a rule-based approach with statistical pruning. They noticed that the decompounding module decreased the 30% lexicon size and improved the 11% word error rate (WER) in the Dutch broadcast news recognition. Erbs et al. (Reference Erbs, Santos, Zesch and Gurevych2015) explored the effect of a decompounding model in keyphrase extraction. They found that the decompounding enhances the word frequency count and identifies more keyphrase candidates in German.

In the past decade, a few studies were also conducted on the corpus-based decompounding models in the Indian languages from NLP and IR perspectives. Deepa et al. (Reference Deepa, Bali, Ramakrishnan and Talukdar2004) used a trie-based dictionary for the splitting of a compound word presented in Hindi speech synthesis. They showed that the algorithm has a split rate of 92–96% of the input compound words, and the percentage of splitting accuracy is 83–87%. Devadath et al. (Reference Devadath, Kurisinkel, Sharma and Varma2014) proposed a hybrid sandhi splitting method in Malayalam. They applied statistical methods and predefined character-level sandhi rules. They observed that the hybrid sandhi splitting method outperformed the rule-based approach. Sahu and Mamgain (Reference Sahu and Mamgain2019) evaluated a corpus-based decompounding model in Sanskrit and improved the splitting accuracy by different ranking methods. They found that the decompounding model enhances precision, recall, and accuracy. Ganguly et al. (Reference Ganguly, Leveling and Jones2013) observed that relaxed and co-occurrence-based constituent selection techniques outperform the standard frequency-based decompounding approach in Bengali IR.

2.2 Machine learning-based decompounding methods

Pellegrini and Lamel (Reference Pellegrini and Lamel2009) investigated an unsupervised data-driven decompounding method in automatic speech recognition for Amharic text. They observed that the decompounding method reduces the out-of-vocabulary (OOV) words from 35% to 50% and slightly reduces the WER. Daiber et al. (Reference Daiber, Quiroz, Wechsler and Frank2015) proposed an analogy-based greedy unsupervised decompounding algorithm for German-to-English machine translation. They noticed that the decompounding algorithm is highly effective for ambiguous compound words. They found that the semantic analogy-based algorithm outperformed the frequency-based approach in German-to-English machine translation. Riedl and Biemann (Reference Riedl and Biemann2016) presented an unsupervised decompounding method in Dutch and German. They observed that the unsupervised method outperformed existing decompounding methods in German; however, the rule-based approach provided better effectiveness in Dutch.

Haruechaiyasak et al. (Reference Haruechaiyasak, Kongyoung and Dailey2008) evaluated the effect of word segmentation in Thai. They looked at two different word segmentation methods. One is a dictionary-based, and the other is a machine-learning approach. In the dictionary approach, they investigated longest matching and maximal matching techniques. In the machine learning approach, they investigated naive bayes, decision tree, support vector machine, and conditional random field techniques. They observed that the conditional random field (CRF) outperformed all other word segmentation methods. Ganguly et al. (Reference Ganguly, Bhat and Biswas2022) proposed a stochastic word transformation skip-gram algorithm, which improves the representation of the compositional compound words by leveraging information from the contexts of their constituents. They noticed that addressing the compounding effect as a part of the word embedding objective outperforms existing compounding-specific post-transformation-based approaches on word semantics and word polarity predictions. Minixhofer et al. (Reference Minixhofer, Pfeiffer and Vulić2023) built a dataset of 255k compound and non compound words across 56 diverse languages. They evaluated the effect of the decompounding method on the large language models (LLMs). They found that the LLMs perform poorly in different languages. Hence, they built self-supervised models that outperformed the unsupervised decompounding models and improved accuracy by 13.9%.

Ajees and Graham (Reference Ajees and Graham2018) presented a hybrid decompounding method in Malayalam. The decompounding method integrates a rule-based and machine-learning approach. The decompounding module can be used as a preprocessing step in machine translation, question-answering, and extractive summarisation applications. Das et al. (Reference Das, Radhika, Rajeev and Raj2012) evaluated the hybrid compound splitting method in the Malayalam text. They used a machine learning approach to classify the word as being split or not. Subsequently, a rule-based sandhi splitter is used to split the word. Shree et al. (Reference Shree, Lakshmi and Shambhavi2016) presented a CRF tool to split a compound word in the Kannada language. They evaluated the model’s effectiveness using five different combinations of training data. They achieved a compound splitting accuracy of 91.19%. Xue (Reference Xue2003) proposed a maximum entropy model for Chinese word segmentation. They found that the model can handle unknown words more efficiently than the maximum matching algorithm. They observed that the maximum entropy model provides precision and recall of 95.01% and 94.94%, respectively.

2.3 Deep learning-based decompounding methods

Chen et al. (Reference Chen, Qiu, Zhu, Liu and Huang2015) proposed an LSTM architecture for Chinese word segmentation. They experimented with different LSTM layers and dropout rates. They observed that the LSTM model provides a precision, recall, and f-score of 97.5%, 97.3%, and 97.4%, respectively. Kitagawa and Komachi (Reference Kitagawa and Komachi2018) also presented an LSTM architecture for Japanese word segmentation. They used a character-based n-gram embedding and a gold dictionary created from the test corpus. They noticed that the model achieves an F1-score of 98.67%. Premjith et al. (Reference Premjith, Soman and Kumar2018) investigated different deep learning-based decompounding methods in Malayalam. They found that the recurrent neural network (RNN), long short-term memory (LSTM), and gated recurrent units (GRU) provide an accuracy of 98.08%, 97.88%, and 98.16%, respectively. Hellwig (Reference Hellwig2015) presented a neural network-based decompounding model in Sanskrit. The neural network comprises an input layer and a hidden forward and backward layer. They used LSTM as a hidden layer to avoid the vanishing gradient problem. They observed that the decompounding model improves precision, recall, and accuracy. Reddy et al. (Reference Reddy, Krishna, Sharma, Gupta and Goyal2018b) introduced a deep sequence to sequence (seq2seq) model that takes the sandhied string as the input and predicts the unsandhied string as output. The model comprises multiple layers of LSTM cells with attention. They achieved an improvement of the F-score of 16.79%.

Hellwig and Nehrdich (Reference Hellwig and Nehrdich2018) developed a Sanskrit word segmentation model using character-level convolutional and RRNs. The model achieves a sentence splitting and string splitting accuracy of 85.2% and 96.7%, respectively. Aralikatte et al. (Reference Aralikatte, Gantayat, Panwar, Sankaran and Mani2018a) presented a double decoder (DD-RNN) with an attention model for the word decompounding in Sanskrit. They found that the model provides the splitting location and prediction accuracy of 95% and 79.5%, respectively, which outperforms the state of art by 20%. They also demonstrate the model’s generalisation capability by applying the word segmentation method in Chinese. Dave et al. (Reference Dave, Singh, D. P. and Lall2021) proposed a two-stage deep learning-based decompounding model in Sanskrit. In the first stage, they predict the sandhi window using the RNN model. In the second stage, the sandhi window is split into two words using the seq2seq model. They observed a location prediction and split prediction accuracy of 92.3% and 86.8%, respectively.

Few researchers developed software tools for decompounding methods in morphologically rich European and Asian languages. Biemann et al. (Reference Biemann, Quasthoff, Heyer and Holz2008) developed a modular ASV toolbox for scientific and educational purposes. The tool supports different sub-modules such as linguistic annotation, classification, clustering, language detection, POS–tagging, named entity recognition, German noun compound splitting, and base form reduction for German, English, and Norwegian. The tool split the compound word recursively using a trie-based data structure. In addition to the above, a prominent Sanskrit sandhi splitter is available on the web. Sachin (2007) proposed a JNU sandhi splitter.Footnote c The sandhi splitting tool is also called a Sanskrit sandhi recogniser and analyser. The tool provides an accuracy of 8.1% in Sanskrit split prediction. Similarly, UoH sandhi splitterFootnote d and INRIA sandhi splitterFootnote e provide a split prediction accuracy of 47.2% and 59.9%, respectively.

Based on the above findings, decompounding models play an important role in text analysis tasks. The effect of the decompounding method is thoroughly investigated in European and a few Asian languages. However, no previous studies exist on decompounding methods in Indian languages like Marathi, Hindi, and Sanskrit from an IR perspective. Hence, we evaluated different decompounding techniques in Indian languages in the IR domain. Our work is motivated by the earlier work of Koehn and Knight (Reference Koehn and Knight2003), Ganguly et al. (Reference Ganguly, Leveling and Jones2013), Ajees and Graham (Reference Ajees and Graham2018), Aralikatte et al. (Reference Aralikatte, Gantayat, Panwar, Sankaran and Mani2018a).

3. Problem formulation

This section introduces the features of the Indian language compound words. A compound word is formed by combining two or more words that create a new word with a specific meaning. The combination generally occurs in two different ways. First, simple concatenation of two or more words following Sandhi Footnote f rules. In the case of simple concatenation, two or more words are combined to generate a new word. For example, in English, ‘note’ and ‘book’ are combined to form ‘notebook’. In sandhi-ed compound word, the last character of the first word and the first character of the second word change at the merging location. For example, ‘vidya’ (meaning education) and ‘alaya’ (meaning house or place) are combined to form ‘vidyalaya’ (meaning school). An Indian language compound word derives the sandhi rules from the Sanskrit language. Three types of Sandhis are defined in azwADyAyIFootnote g as given below.

  1. (1) Swara Sandhi: Here, the constituents of the compound word are combined at the merging locations of vowels. i.e. vowels are the last character of the first word and the first character of the second word. For example, ‘jana’ and ‘adesha’ are combined to form ‘janadesha’.

  2. (2) Vyanjana Sandhi: Here, constituents are combined at the merging location, which is a consonant. i.e. either the last character of the first word or the first character of the second word is a consonant, or both are consonants. For example, ‘sat’ and ‘jana’ are combined to form ‘sajana’.

  3. (3) Visarga Sandhi: In this rule, the last character of the first constituent word is a ‘visarga’. It means that a Devanagari script character placed at the end of a word generates an additional H sound. For example, ‘antaH’ and ‘gata’ are combined to form ‘antargata’.

In this study, we consider only the closed compound words, which means that two constituent words do not have a word boundary between them. Moreover, we do not consider the hyphens as word delimiters and do not split the hyphenated words. The word decompounding method requires correct syntactic splitting to obtain semantically meaningful constituent words. In word decompounding, there are two important tasks: 1. detecting the location of the split point and 2. splitting the compound word into two different constituents. The tasks get more complicated because of the different morphological features of Indian languages. An Indian language compound word can be split into multiple ways. Hence, detecting the splitting point location is a difficult task. A compound word ‘ $w$ ’ may be formed by concatenating two or more words, i.e. $w_1, w_2, \ldots, w_n$ . However, in this work, we split the compound word into two parts only.

4. Different decompounding methods

Decompounding is used as an essential preprocessing step in the morphologically rich European and Asian languages. However, the impact of decompounding has been less explored in the Indian languages. This study explores the impact of decompounding in low-resource Indian languages from an IR perspective.

4.1 Corpus-based decompounding approaches

We evaluate here some of the existing decompounding techniques that have provenly yielded high effectiveness in different morphologically rich European and Asian languages Koehn and Knight (Reference Koehn and Knight2003), Deepa et al. (Reference Deepa, Bali, Ramakrishnan and Talukdar2004), Ganguly et al. (Reference Ganguly, Leveling and Jones2013). The impact of decompounding has been investigated from an NLP perspective. However, we study it from the IR viewpoint. In the corpus-based decompounding approach, the dictionary comprises the simple words of the document collection.

4.1.1 Frequency-based approach

In this approach, we split the compound words based on the frequency of probable constituents in the collection. The more frequently a probable constituent independently occurs in the collection, the more likely it is to be a part of a given compound word. This insight defines that a splitting point of a word depends upon the frequency of the constituent words in the collection. The splitting point of a compound $S$ is detected by the highest geometric mean obtained among considering word frequencies of all possible splits ( $e_i$ ) given by equation (1) ( $n$ being the number of splits, we consider here $n=2$ only). This approach is in line with the earlier work of the compound splitting method applied in the German-English machine translation Koehn and Knight (Reference Koehn and Knight2003).

(1) \begin{equation} \mbox{argmax}_{S}{\left(\prod _{e_i \in S} \mbox{frequency}(e_i)\right)}^{\frac{1}{n}} \end{equation}

4.1.2 Maximum-branching factor approach

Here, we explore a language-independent decompounding technique that can be applied to any compounding language. The decompounding is implemented in two steps. The first step detects the split point location, and the second step validates the morpheme so identified. In the first step, we create a lexical character-based tree, where each node represents a character, and a word can be found by traversing the path of the tree to a leaf node. From the tree, a split point location is identified based on the frequency of the constituent terms (the prefix and the suffix part of a complete path). In the second step, we validate the morpheme boundary using a dictionary. This approach is in line with the earlier work of the compound splitting method applied in German LVCSR Adda-Decker (Reference Adda-Decker2003).

4.1.3 Trie-based approach

Here, we use a trie-based dictionary to split the compound words. A potential compound word is detected if the currently processed word is part of a word already present in the trie or a word in the trie is a substring of the current word. At first, we store the prefix in a trie-based dictionary and look for potential candidate words to form a compound word. For example, in the compound word ‘underworld’, the algorithm traverses the trie-based dictionary, stores the prefix ‘under’, and looks for the candidate word ‘world’ by traversing the dictionary and then decompound the word ‘underworld’ into ‘under’ and ‘world’. We also use the prefix list (Table A.1) and apply sandhiFootnote h rules to deal with the morphological features of Indian languages. However, the previously evaluated decompounding in Hindi speech synthesis Deepa et al. (Reference Deepa, Bali, Ramakrishnan and Talukdar2004) does not consider the morphological characteristics of Indian languages.

4.1.4 Co-occurrence-based decompounding approach

In this approach, we first split the compound words using the frequency-based approach described above. We also apply relaxation and co-occurrence-based techniques to deal with the morphological features of Indian language compound words. The relaxed decompounding technique does not split the prefix-based compound words such as ‘upanagar’ into ‘upa’ and ‘nagar’ the co-occurrence-based decompounding technique tries to avoid some of the wrong splitting of the frequency-based approach. For example, in the frequency-based approach, the word ‘Loksabha’ is split into ‘lok’ and ‘sabha’ due to the high frequency of compound constituents in the collection. However, in the co-occurrence-based technique, the compound word ‘Loksabha’ is not split into ‘Lok’ and ‘sabha’ because the terms ‘Lok’ and ‘sabha’ will not frequently co-occur in the document collection. The co-occurrence-based decompounding technique splits the compound word into constituents only if the compound constituents co-occur with the compound word higher than a particular threshold. Here, we consider an optimal threshold value $\tau = 0.2$ for different Indian languages as we find $\tau = 0.2$ provides the best retrieval effectiveness in Bengali IR Ganguly et al. (Reference Ganguly, Leveling and Jones2013). The co-occurrence measure is the overlap coefficient between the set of documents $D(c)$ containing the constituent term $c$ and $D(w)$ containing the compound word. We measure the overlap coefficient by equation (2). This approach aligns with the earlier work of the compound splitting method evaluated in Bengali IR Ganguly et al. (Reference Ganguly, Leveling and Jones2013).

(2) \begin{align} Overlap (w,c)=\frac{\left | D(w) \bigcap D(c) \right |}{min{\left \{ \left | D(w) \right |,\left | D(c) \right | \right \}}} \\[-24pt] \nonumber \end{align}

4.2 Machine learning-based decompounding methods

Basic machine learning models such as support vector machine (SVM), decision trees, CRF, and random forests are widely used in different computational areas like text classification, part-of-speech (POS) tagging, and other NLP tasks. However, these models are yet to be explored in the word decompounding task for Indian languages. Here, we evaluate the impact of different hybrid (dictionary and machine-learning-based) decompounding models in different Indian languages. We used machine learning models such as decision tree, random forest, $k$ -nearest neighbours, SVM, and CRF. At first, we split the simple concatenation of compound words using a dictionary in each language. To split sandhi-ed compound words, we use different machine learning models. We train the machine learning models using a set of training examples. The training examples comprise three types of sandhi as described in Section 3. Post-training, the models are checked using compound words from the test dataset and evaluation is done by looking at the change in the retrieval effectiveness of different IR techniques. Here, we briefly describe different ML techniques used in this context, followed by the general steps adopted for these machine learning-based decompounding models.

4.2.1 Decision tree approach

The decision tree Quinlan (Reference Quinlan1986) follows a tree-like structure, where each internal node represents the test, the branch represents the outcome of the test, and the leaf node represents the decision after computing all the attributes. In the decompounding method, the root node represents the compound word, and the children nodes represent the individual constituent words. This process is repeated recursively. The recursion is completed when each leaf node contains the constituent word. The decision tree construction does not require domain knowledge or parameter settings; hence, it is appropriate for exploratory knowledge discovery.

4.2.2 Random forest approach

Random forest Ho (Reference Ho1995) takes a variety of decision trees and averages the effectiveness of all trees to improve the splitting accuracy of the system. Instead of just focusing on one decision tree, the random forest model uses multiple decision trees, and prediction is based on the majority of votes for the prediction of different trees. This approach is based on ensemble learning, combining multiple trees to improve the system’s effectiveness. More trees in the forest lead to higher accuracy and prevent the over-fitting problem.

4.2.3 $k$ -nearest neighbours approach

The k-nearest neighbours algorithm Cover and Hart (Reference Cover and Hart1967) assumes that similar objects are close to each other. In this algorithm, the nearer neighbours contribute more to the average than the distant ones. The algorithm depends upon the distance function. If the features belong to different classes, normalising the training data improves the system’s efficiency. The neighbours are treated as the training set for the algorithm so that the algorithm does not require any explicit training data. The training example comprises a multidimensional feature vector with each class labelled.

4.2.4 Conditional random field approach

Machine learning models are broadly categorised into two types: the generative models and the discriminative models. A conditional random field Lafferty et al. (Reference Lafferty, McCallum and Pereira2001) is a discriminative model that predicts the current task based on the contextual information or state of the neighbours. The discriminative model encodes many features from the input data and enhances the effectiveness of the prediction. CRF is mainly designed to label and segment sequence data. In recent years, CRF and SVM have been widely used in different NLP applications like POS tagging and named entity recognition, providing the best results in various computational tasks. So, we evaluate the model’s effectiveness in decompounding tasks in Indian languages.

4.2.5 Support vector machine approach

SVM Cortes and Vapnik (Reference Cortes and Vapnik1995) is a supervised learning algorithm primarily used for classification tasks. Suppose we have a set of training samples $D$ = ( $x_1, y_1$ ), …, ( $x_m, y_m$ ), where $x_i$ is the feature vector of $i$ th training sample, $y_i$ is the output class of $i$ -th training sample, and ‘ $m$ ’ being the number of training samples. The main idea behind SVM is to classify the samples into two or more classes by a hyperplane. SVM finds a hyperplane that maximises its margin. SVM chooses the extreme points near the boundaries that help create a hyperplane. The extreme points are called support vectors; hence, the algorithm is called a support vector machine.

Algorithm for machine learning-based decompounding approaches

The basic machine learning-based decompounding model is implemented in the following steps. We first split the simple concatenation of compound words followed by the sandhi-ed compound word.

  1. (1) Read a set of input tokens from the user.

  2. (2) Remove the stopwords from the input tokens.

  3. (3) For each prefix in the prefix list (Table 12) ( $L_{pre}$ ), check whether the prefix is there in the given token or not. If yes, consider the entire input word as a compound word only.

  4. (4) Check the length of the word in each token. If the token length is less than seven ( $7$ ), then EXIT.

  5. (5) If the word length exceeds six ( $6$ ), traverse the dictionary and look for any compound constituent present; if yes, break that compound word into its constituent morphemes.

  6. (6) If any of the above conditions are not satisfied, check for the sandhi-ed compound word splitting. Sandhied compound word splitting

  7. (7) Assign a numeric number (Unicode) to each letter in the Devanagari script.

  8. (8) Train different machine learning models by training datasets. The training dataset comprises the compound words and their constituent morphemes. Store the number corresponding to the first morpheme’s last and second morpheme’s first character in the training dataset.

  9. (9) During training, the machine learning model learns from different sandhi examples.

  10. (10) During testing, the machine learning model classifies the compound words into one of the trained sandhi examples and generates constituent morphemes.

  11. (11) After decompounding, different retrieval models are applied to evaluate the change in retrieval effectiveness using the MAP scores.

The primary difficulty in developing a machine learning-based decompounding model is that it requires enormous training data. We also observe that the machine-learning-based model requires a complex feature representation. Hence, we also evaluate the deep learning-based decompounding models.

4.3 Deep learning-based decompounding approaches

In recent years, neural network models such as RNN, LSTM, and GRU have shown to provide good effectiveness in the text segmentation task of Chinese Chen et al. (Reference Chen, Qiu, Zhu, Liu and Huang2015), Japanese Kitagawa and Komachi (Reference Kitagawa and Komachi2018), and Sanskrit Hellwig (Reference Hellwig2015), Hellwig and Nehrdich (Reference Hellwig and Nehrdich2018), Reddy et al. (Reference Reddy, Krishna, Sharma, Gupta, M R and Goyal2018a). However, these neural network models have not yet been evaluated in the word decompounding task of Indian languages. This study explores different word decompounding models based on deep learning, such as RNN, LSTM, and GRU, its bidirectional versions, such as Bi-RNN, Bi-LSTM, Bi-GRU, and attention versions, such as Bi-RNN with attention (referred to as Bi-RNN-A), Bi-LSTM with attention (referred to as Bi-LSTM-A) and Bi-GRU with attention (referred to as Bi-GRU-A) model and evaluates their effectiveness in the Indian language IR. The decompounding task is seen here, in a sense, similar to the language translation problem – as the sequence of characters or compound words is taken as input and produces another sequence of characters or decompounded words as output. The sequence-to-sequence model Sutskever et al. (Reference Sutskever, Vinyals and Le2014) is widely used in the NLP domain. Here, we use the same model for word decompounding in Indian languages. The proposed model uses an RNN-based two-stage deep neural network for compound word splitting. The step for the decompounding algorithm is given below. The code is implemented in Python 3.5 with Keras API running on the Tensor Flow back-end. The code for different decompounding models is publicly available on GitHub.Footnote i

4.3.1 Encoder-decoder model

The proposed encoder–decoder model is inspired by the character level sequence to sequence model Sutskever et al. (Reference Sutskever, Vinyals and Le2014). The encoder comprises one recurrent layer, i.e. RNN, LSTM, or GRU, and converts the input character sequence into a one-hot encoding vector and processes it to the subsequent layer. Similarly, the decoder comprises one recurrent layer (RNN, LSTM, or GRU) followed by a dense soft-max layer. For training, we use the Marathi dataset developed by Singh et al. (Reference Singh, Bhingardive and Bhattacharyya2016) and SanskritFootnote j dataset developed at the University of Hyderabad. We train the encoder–decoder model by providing a compound word at a time and corresponding decompounded words concatenated with a ‘+’ in between. The input and output character sequences are replaced by their one-hot encoded vector sequences. Characters ‘&’ and ‘$’ are used as start and end markers in the output sequence. The output of the encoder–decoder model is the same one-hot encoded vector of decompounded words but with a left shift of characters by length one, i.e. offset by a one-time step in the future. We use a two-stage deep neural network for compound splitting. The reason behind using this two-stage deep neural network is that it detects the splitting point location efficiently Dave et al. (Reference Dave, Singh, D. P. and Lall2021), Aralikatte et al. (Reference Aralikatte, Gantayat, Panwar, Sankaran and Mani2018b). In the first stage, the model predicts a sandhi-window (a maximum of 5-letter window where at least two letters come from the first constituent word and at least another two letters from the second constituent word). In the second stage, the most probable splits that are likely to constitute the compound word are identified. Both the stages use the seq2seq model.

In the first stage, we provide a compound word as input to the sequential model that the model converts into a one-hot encoding vector and stores it in an array. All the array elements are assigned value zero except the sandhi window element, which is assigned value one, as shown in Figure 1 (the highlighted letters constitute sandhi-window). In the second stage, using the sandhi window, we split the compound word into two words. The input sequence is a sandhi window, and the output sequence is two words with a space delimiter between them. The model architecture of sandhi splitting is shown in Figure 2. The model is trained by the Adam optimiser Kingma and Ba (Reference Kingma and Ba2015) and the categorical cross-entropy loss function. The training vectors are divided into a batch size of 64. In the encoder–decoder model, we experiment with a different version of sequential models and parameters and the best MAP score achieved at a given parameter setting is shown in Table 1. At first, we trained the basic RNN model, but the model was not effective in different Indian languages. Hence, we experiment with other sequential models such as Bi-RNN, Bi-RNN-A, LSTM, Bi-LSTM, Bi-LSTM-A, GRU, Bi-GRU, and Bi-GRU-A. A detailed explanation of different sequential models is given below.

Figure 1. Sandhi-window (AnaNg) as the prediction target in a compound word.

Figure 2. Model architecture for Sandhi Split – Stage 1.

4.3.2 Recurrent neural network (RNN)

Recurrent neural network (RNN) Medsker and Jain (Reference Medsker and Jain2001) is a class of artificial neural networks which deals with the variable length sequential data $X$ = ( $x_1, x_2, \ldots, x_t, \ldots$ ). RNN uses memory at each internal node to process variable-length sequential data. In an RNN, the output state $h(t)$ depends on the previous state information $h(t-1)$ and present input $x_t$ . At any time-step $t$ , the value of the current state is updated by the equation (3). A basic RNN architecture is shown in Figure 3.

(3) \begin{equation} h(t)=f(h(t-1), x_t) \end{equation}

Figure 3. A basic RNN architecture.

where $f$ represents the nonlinear activation function. In a simple RNN, we use the soft-max activation function. We train the RNN by gradient-descent methods and back-propagation. In each training iteration, the gradient is evaluated and updated with the current weight. During the training of sequential data, the gradient will not be updated, which will prevent changes in the RNN model’s weight. Hence, the model does not learn from the previous inputs, which causes the vanishing gradient problem. We use other sequential models like LSTM and GRU to overcome the vanishing gradient problem.

4.3.3 Long short-term memory network (LSTM)

The traditional RNN suffers from the problem of vanishing gradient. Hence, the RNN could not handle the long-term sequential data. To overcome the vanishing gradient problem, Hochreiter and Schmidhuber (Reference Hochreiter and Schmidhuber1997) proposed an LSTM network. The LSTM network can resolve the issue by maintaining different memory blocks and gates. The memory block comprises memory cells with self-connections, and different gates are used to regulate the flow of information. Primarily, the LSTM network comprises four types of gates, i.e. input gate, output gate, forget gate and memory-cell activation gate, as described below.

Table 1. Show the Parameter of different Encoder–Decoder models

  1. (1) Input gate: The input gate ( $i_t$ ) determines which input should be kept at the cell state and which input is transmitted to the next long-term state, i.e. $c_t$ . The gate determines that some part of the information is transmitted and reflected in long-term memory.

  2. (2) Forget gate: The forget gate ( $f_t$ ) determines which part of the long-term data should be kept and passed to the next state ( $c_t$ ) and which part of the long-term data is to be thrown away from the cell state. The decision is made by the sigmoid layer called the ‘forget gate layer’.

  3. (3) Memory-cell activation gate: The memory-cell activation gate ( $c_t$ ) updates the information in the memory state cell by taking the information from the input gate and forget gate.

  4. (4) Output gate: The output gate ( $o_t$ ) determines which part of the long-term state should appear in the output network.

  5. (5) Mathematical expressions of different gates are as follows.

    (4) \begin{equation} i_t= \sigma (W_{xi}\cdot x_t + W_{hi}\cdot h_{t-1}+W_{ci}\cdot c_{t-1}+b_i) \end{equation}
    (5) \begin{equation} f_t= \sigma (W_{xf}\cdot x_t + W_{hf}\cdot h_{t-1}+W_{cf}\cdot c_{t-1}+b_f) \end{equation}
    (6) \begin{equation} o_t= \sigma (W_{xo}\cdot x_t+W_{ho}\cdot h_{t-1}+W_{co}\cdot c_{t-1}+b_o) \end{equation}
    (7) \begin{equation} c_t = f_t \cdot c_{t-1} + i_t \cdot \tanh (W_{xc}\cdot x_t + W_{hc}\cdot h_{t-1}+b_c) \end{equation}

A hidden state is represented as follows:

(8) \begin{equation} h_t= o_t \cdot \tanh (c_t) \end{equation}

$W_{xi}, W_{xf}, W_{xo}, W_{xc}$ are the weight matrices of different layers connected to the input vector $X_t. W_{hi}, W_{hf}, W_{ho}, W_{hc}$ are the weight matrices connected to the state $h_{t-1}$ and $ b_i, b_f, b_o, b_c$ are the biases at different layers. A single-cell LSTM architecture is shown in Figure 4.

Figure 4. A single cell LSTM architecture.

4.3.4 Gated recurrent unit (GRU)

A gated recurrent unit is a variant of RNNs like RNN and LSTM introduced by Cho et al. (Reference Cho, van Merriënboer, Gulcehre, Bahdanau, Bougares, Schwenk and Bengio2014). GRU also solves the problem of vanishing gradient. GRU is like an LSTM network but is comprised of fewer parameters and gates.

  1. (1) Update gate: The update gate ( $z_t$ ) determines the amount of information transferred from one hidden state to the next hidden state. If the output gate is close to 1, then all current hidden state information is transferred to the next hidden state.

  2. (2) Reset gate: The reset gate ( $r_t$ ) determines the significance of previously hidden state information in updating current hidden state information. If the output of the reset gate is close to 0, the hidden state is forced to ignore the previously hidden state information and reset with the current input only. It signifies that the hidden state can drop any information that is found to be irrelevant, allowing a more compact representation.

  3. (3) Hidden state: The hidden state ( $h_t$ ) is updated using the current input and the information obtained from the previous hidden state ( $h_{t-1}$ ). Mathematical expressions of different gates are as follows.

    (9) \begin{equation} z_t = \sigma (W_{z}\cdot x_t + U_{z}\cdot h_{t-1}+b_z) \end{equation}
    (10) \begin{equation} r_t = \sigma (W_{r}\cdot x_t + U_{r} \cdot h_{t-1}+b_r) \end{equation}
    (11) \begin{equation} h_t = (1-z_t) \cdot \tanh (r_t \cdot U \cdot h_{t-1} + W \cdot x_t) + z_t \cdot h_{{t-1}} \end{equation}

$W_{z}, W_{r}$ , and $W$ are the weight matrices of different layers connected to the input vector $X_t$ , while $U_r$ , $U_z$ , and $U$ for the $U$ for $h_{t-1}$ . $b_z$ , and $b_r$ are the biases at different layers. A single-cell GRU architecture is shown in Figure 5.

Figure 5. A single cell GRU architecture.

5. Experimental setup

Deep learning-based decompounding models for different Indian languages are evaluated in the following steps. The proposed decompounding models can split the simple concatenation and sandhi-ed compound words.

  1. (1) Neural network models are implemented using Keras library.Footnote k

  2. (2) During compound splitting, the prefix-based compound word (Table A1) ( $L_{pre}$ ) with word length less than seven and larger length compound words (length greater than $20$ ) are ignored. The larger length of compound words reduces the effectiveness of decompounding models; hence, we ignore those compound words.

  3. (3) Different neural network models such as (RNN, LSTM, or GRU) are trained on both the simple concatenation and sandhi-ed compound words.

  4. (4) The neural network models are tested on FIREFootnote l text collection for different Indian languages.

  5. (5) In the document collection, each compound word is replaced with its split words. The stopwords are removed from the document collection, and the effectiveness of decompounding models is evaluated in the IR settings.

  6. (6) The MAP scores of the baseline approach (unmodified document collection) are compared with the split version of the compound word in the collection (modified document collection).

6. Information retrieval framework

To evaluate the effectiveness of different decompounding models, we use an open-source search engine called TerrierFootnote m IR system for indexing and retrieving the document collection. We primarily used the following retrieval models: probabilistic retrieval models (BM25 and TF-IDF), DFR-based retrieval models (In_expC2, BB2, InL2), and the Language model. The mathematical expression of different retrieval models is given below. Each mathematical expression presents the weight of the term (t) in document (d), that is, w(t,d).

6.1 BM25 model

Okapi BM25 Robertson et al. (Reference Robertson, Walker and Beaulieu2000) is a popular model where BM stands for ‘best matching’. The term weight of a query term in a document is given by Equation 12.

(12) \begin{equation} w(t,d)= tf_{\textrm{d}} \cdot (\frac{\log (\frac{N-n+0.5}{n+0.5})}{k_{\textrm{1}} \cdot ((1-b)+b \cdot \frac{dl}{avdl}+tf_{\textrm{d}}) }) \end{equation}

6.2 TF-IDF model

In this model, the importance of a query term in a document is determined by the combination of term frequency (tf) and inverse document frequency (idf). Here, the tf represents the frequency of a term present in a given document, and idf is the inverse of document frequency (df) where df represents the number of documents that contain the given term. We call this quantity as term-weight ( $w(t,d)$ ) of term $t$ in document $d$ . The scalar combination of all such $w(t,d)$ s in the query terms is used in cosine-similarity. The TF-IDF model within the Terrier retrieval system uses Robertson’s tf and Sparck Jones idf Sparck Jones (Reference Sparck Jones1972).

(13) \begin{equation} w(t,d)= Robertson\_tf \cdot idf \end{equation}

where,

$$Robertson\_tf = \frac{{t{f_{\text{d}}}}}{{{k_{\text{1}}}\cdot((1 - b) + b\cdot\frac{{dl}}{{avdl}}) + t{f_{\text{d}}}}}idf = \log (N/{d_{\text{f}}} + 1)tfn = tf\cdot{\log _2}(1 + c\cdot\frac{{avdl}}{l})$$
\begin{eqnarray*} dl &:& \text{document length in number of terms}\\[5pt] avdl &:& \text{average document length}\\[5pt] d_{\textrm{f}} &:& {\text{document frequency of term} {\;} \{t\}}\\[5pt] N &:& \text{total number of documents in the collection}\\[5pt] n &:& \text{number of documents containing at least one term}{\;\{t\}}\\[5pt] k_{\textrm{1}} &:& \text{term-frequency parameter, a constant}\\[5pt] b &:& \text{document length normalization parameter} \\[5pt] n_{\text{t}} &:& \text{document frequency of term}{\;\{t\}} \\[5pt] tfn &:& \text{normalised term frequency} \\[5pt] c &:& \text{free parameter} \\[5pt] F &:& {\text{frequency of term}{\;}\{t\} \text { in the collection}} \end{eqnarray*}

We also consider other probabilistic models such as In_expC2, BB2, and InL2. These models come from the divergence from randomness (DFR) family Amati and Van Rijsbergen (Reference Amati and Van Rijsbergen2002). The DFR models are based on the idea that the more the divergence of the within-document term frequency from its frequency within the collection, the more information is carried by the term ( $t$ ) in the document ( $d$ ) Robertson et al. (Reference Robertson, van Rijsbergen and Porter1980).

6.3 In_expC2 model

In this model, the relevance score of a document is calculated by Equation (14).

(14) \begin{equation} w(t,d)= \frac{F+1}{n_t(tfn_e+1)}\big (tfn_e\cdot \log _2\frac{N+1}{n_e+0.5}\big ) \end{equation}

$tfn_e$ denotes the normalised term frequency. A modified version of normalisation two is given by

(15) \begin{equation} tfn_e=tf\cdot \log _e(1+c\frac{avdl}{l}) \end{equation}

6.4 BB2 model

In the Bose–Einstein model for randomness, the weight of a query term in a given document is given by the ratio of two Bernoulli’s processes (first normalisation and second normalisation) for term frequency normalisation as shown in Equation (16).

(16) \begin{equation} \begin{split} w(t,d)= \frac{F+1}{n_t\cdot (tfn+1)} & \big [(-\log _2(N-1)-\log _2(e) \\ & \quad +f(N+F-1,N+F-tfn-2) -f(F,F-tfn)\big )] \end{split} \end{equation}
(17) \begin{equation} tfn=tf\cdot \log _2(1+c\cdot \frac{avdl}{l}) \end{equation}

where,

\begin{eqnarray*} F &:& \text{frequency of term}\; \textit{t}\; \text{ in the collection}\\ n_t &:& \text{document frequency of term}\; \textit{t}\\ tfn &:& \text{normalised term frequency} \\ c &:& \text{ free parameter} \end{eqnarray*}

6.5 InL2 model

In this model, the weight of a query term in a document is given by the ratio of two Laplace processes (first normalisation and normalisation 2) for term frequency normalisation as shown in equation (18).

(18) \begin{equation} w(t,d)= \frac{1}{tfn+1}\big (tfn\cdot \log _2\frac{N+1}{n_t+0.5}\big ) \end{equation}

6.6 Hiemstra language model

We also evaluate using a non-parametric probabilistic or language model proposed by Hiemstra (Reference Hiemstra2001). The probability of a query term $t$ in a document $d$ depends upon the term frequency of $t$ in both $d$ and the entire corpus. This model uses a smoothing parameter $\lambda$ to tune their contribution (a popular default value of $\lambda$ is $0.15$ ). The similarity between a query term $t$ and document $d$ is given by Equation 19.

(19) \begin{equation} P(D, T_{1}, T_{2}, T_{3}, \cdot \cdot \cdot \cdot T_{n}) = P(D)\prod _{i=1}^{n}((1-\lambda _{i}) P(T_{i})+ \lambda _{i} P(T_i |D)) \end{equation}

where D is a document and $T_{i}$ are query terms.

7. Evaluation metrics

We used the following metrics to investigate the effectiveness of decompounding models in the IR domain.

7.1 Precision

It is the fraction of relevant documents retrieved among the retrieved documents.

(20) \begin{equation} Precision = \frac{\left |\text{Relevant documents} \bigcap \text{Retrieved documents}\right |}{\text{Total number of retrieved documents}} \end{equation}

7.2 Recall

It is the fraction of relevant documents retrieved from a set of relevant documents.

(21) \begin{align} Recall = \frac{\left |\text{Relevant documents} \bigcap \text{Retrieved documents} \right |}{\text{Number of relevant documents in the collection}} \end{align}

In both, the numerator is the number of relevant and retrieved documents. To improve the performance of any system, we improve precision and recall everywhere – which essentially requires an increase in the number of relevant retrieves (Rel.Ret.).

7.3 AP

It is the average of the precision values whenever a relevant document is retrieved. R $_{\textrm{d}}$ stands for the d-th relevant document among a ranked list of retrieved documents. The total number of relevant documents for a given query is ‘R’.

(22) \begin{equation}{average precision} (AP) =\frac{1}{R}\sum _{d=1}^{R}{precision(R _{\textrm{d}})} \end{equation}

7.4 MAP

AP corresponds to a single query. However, the comparison between two IR models should not be based on a single query but on a set of queries so that variation in retrieval effectiveness over individual queries is averaged out. Hence, MAP is defined for a set of queries and is computed as the simple arithmetic mean of AP scores of all such queries.

(23) \begin{equation}{mean average precision} (MAP)= \frac{1}{|Q|}\sum _{t=1}^{|Q|}{AP(t)} \end{equation}

$|Q|$ : Number of queries

8. Test collection

In this work, we experimented with the Marathi, Hindi, and Sanskrit test collections. The Marathi and Hindi test collection downloaded from FIREFootnote n evaluation campaign. We built a small test collection in Sanskrit and experimented with it. These corpora primarily comprise news articles extracted from different domains. The news article includes politics, business, sports, science, and other current affairs covering almost all walks of life. Each collection comprises a set of documents and queries. The statistic of different test collections is shown in Table 2. Each query consists of three logical sections, i.e., a brief title (under $\lt$ TITLE $\gt$ tag), followed by a description tag ( $\lt$ DESC $\gt$ tag) and a narrative tag ( $\lt$ NARR $\gt$ tag). This experiment considers only a query’s Title (T) section. In the collections, both topics and documents use the UTF-8 encoding system.

Table 2. Statistics of text collection

9. Experimental setup

We implemented different decompounding models to split the Indian language compound words. Moreover, we evaluated the effectiveness of decompounding models in the IR domain by the following steps.

  1. 1. Apply different decompounding models in Indian languages described in Section 4.

  2. 2. Perform retrieval experiments using different retrieval models and calculate the MAP score and the number of relevant retrieved documents.

  3. 3. Compared the MAP scores and a number of relevant retrieved documents with no decompounding approach (none) as the baseline.

  4. 4. Compared the MAP score and a number of relevant retrieved of different decompounding approaches (corpus-based, hybrid machine learning-based, and deep learning-based) in different Indian languages IR.

Primarily, we explore the following research questions in the decompounding methods in the Indian language IR.

  1. 1. Does word decompounding impact the Indian language IR? If yes, to what extent? In this experiment, we evaluate the impact of different decompounding techniques in the Indian language IR.

  2. 2. Can corpus-based, machine learning based, and deep learning-based decompounding models be used in the Indian language IR? If yes, how? In this experiment, we presented different corpus-based, hybrid machine learning-based and deep learning-based decompounding models and evaluated their effectiveness in Indian languages IR.

  3. 3. Among the different decompounding models (corpus-based, hybrid machine learning-based, and deep learning-based), which provides the best effectiveness in the IR domain? In this experiment, we compared the MAP score of different decompounding models and suggested the best-performing model for a language.

  4. 4. Among the different IR models, which provides the best effectiveness from the IR perspective? In this experiment, we evaluated different IR models and suggested the best-performing model for a language.

10. Experimental results

To address the research questions (RQs) described in Section 1, we detail the results and our observations below.

10.1 Effect of corpus-based decompounding on retrieval

In the first set of experiments, we evaluate the impact of different corpus-based decompounding models in Indian language IR. The effect of different corpus-based decompounding models for Marathi, Hindi, and Sanskrit languages is shown in Tables 3, 4, and 5, respectively. In these tables, the best MAP scores among the retrieval models are shown in boldface. It is observed that the different corpus-based decompounding models improve retrieval effectiveness in different Indian languages IR. However, the effect of decompounding models varies from one language to another. The frequency-based decompounding model improves an MAP score of 12.94% in Marathi, 4.56% in Hindi, and 0.37% in Sanskrit (In_expC2 model). Similarly, the maximum branching factor, tri-based, and co-occurrence-based decompounding models improve the MAP scores by 13.5%, 13.87%, and 14.98% in Marathi, 4.34%, 4.22%, and 4.86% in Hindi, and 2.8%, 4.75%, and 4.58% in Sanskrit languages, respectively (In_expC2 model). Other models also show improvements in general, although at different levels, including some drops. These observations are in line with earlier findings as different corpus-based decompounding models provide comparable effectiveness in the European languages IR Monz and Rijke (Reference Monz and Rijke2001).

Table 3. MAP scores of different corpus-based decompounding evaluation in Marathi (39 T queries)

Table 4. MAP scores of different corpus-based decompounding evaluation in Hindi (50 T queries)

Table 5. MAP scores of different corpus-based decompounding evaluation in Sanskrit (50 T queries)

10.2 Effect of machine learning-based decompounding on retrieval

In the second set of experiments, we propose hybrid machine learning-based decompounding models followed by their evaluation. The decompounding models comprise the dictionary and machine learning-based approach to split the compound words. Impact of different hybrid machine learning-based decompounding models on Marathi, Hindi, and Sanskrit languages is shown in Tables 6, 7 and 8, respectively. It is observed that the different decompounding models enhance the effectiveness of document retrieval. On closer observation, we find that the effect of decompounding models varies from one language to another. The SVM model improves MAP score by 22.08% in Marathi, 10.59% in Hindi and 2.95% in Sanskrit languages. Similarly, the CRF, KNN, Decision Tree, and Random Forest-based models improve MAP scores by 22.27%, 15.73%, 16.84%, and 16.7% in Marathi; 10.83%, 16.41%, 16.65% and 17.14% in Hindi; and 2.82%, 4.75%, 4.58% and 4.43% in Sanskrit languages, respectively (all in In_expC2 model). In other models, the scores also mostly improve with a few exceptions. Different hybrid machine learning-based models outperform the pure corpus-based models in Indian and European languages IR Monz and Rijke (Reference Monz and Rijke2001), Ganguly et al. (Reference Ganguly, Leveling and Jones2013). The fundamental reason behind this is that the machine learning-based decompounding models can efficiently split the simple concatenation and sandhi-ied compound words.

Table 6. MAP scores of different hybrid machine learning-based decompounding evaluation in the Marathi (39 T queries)

Table 7. MAP scores of different hybrid machine learning-based decompounding evaluation in the Hindi (50 T queries)

Table 8. MAP scores of different hybrid machine learning-based decompounding evaluation in the Sanskrit (50 T queries)

10.3 Effect of deep learning-based decompounding on retrieval

In the third set of experiments, we propose different deep learning-based decompounding models and evaluate their effectiveness from an IR perspective. The impact of different deep learning-based decompounding models for Marathi, Hindi, and Sanskrit languages is shown in Tables 9, 10, and 11. Deep learning-based decompounding models are seen to considerably improve the effectiveness of an IR system. However, the impact of deep learning-based decompounding models varies from one language to another. The RNN-based decompounding model improves MAP score of 23.66% in Marathi, 16.28% in Hindi,and 2.38% in Sanskrit compared to the baseline approach (In_expC2 model). Similarly, the LSTM and GRU models improve MAP score by 23.94% and 23.66% in Marathi, 17.02% and 16.84% in Hindi, 4.94% and 1.15% in Sanskrit. We observe no significant difference in MAP score between the vanilla RNN, LSTM, or GRU and their bidirectional counterparts. However, the Bi-RNN-A-based decompounding model improves MAP score by 27.61% in Marathi, 18.18% in Hindi, and 6.1% in Sanskrit compared to the baseline approach (In_expC2 model). Similarly, the Bi-LSTM-A and Bi-GRU-A decompounding models improve MAP score by 28.02% and 27.98% in Marathi, 17.11% and 17.45% in Hindi, 5.24% and 2.83% in Sanskrit. Among the different deep learning-based decompounding models, the attention-based models outperform the other models in the Indian language IR. We also observe that the deep learning-based models for word-decompounding outperform the hybrid machine learning-based and corpus-based models in Indian language IR.

Table 9. MAP scores of different deep learning-based decompounding evaluation in the Marathi (39 T queries)

Table 10. MAP scores of different deep learning-based decompounding evaluation in the Hindi (50 T queries)

Table 11. MAP scores of different deep learning-based decompounding evaluation in the Sanskrit (50 T queries)

10.4 Retrieval effectiveness analysis: some insights

In this work, the statistically significant differences are detected by a two-sided t-test (significance level $\alpha$ = 5%) with Bonferroni correction Simes (Reference Simes1986). We use without decompounding as a baseline (Tables 9, 10 and 11). We also observe that the decompounding methods typically improve MAP scores in different retrieval models across the Indian languages, but the changes in effectiveness are not statistically significant. To get more insights into the effect of decompounding, we perform a query-by-query analysis. Here, we consider the In_expC2 model for Marathi and Hindi languages and the BB2 model for Sanskrit as the best-performing models for their respective languages. On closer observation, we find that the Bi-LSTM-A model improves the average precision scores in 28 topics and reduces in 5 topics in Marathi. The percentage change in the average precision score for each query is shown in Figure 6. Similarly, the Bi-RNN-A model improves the average precision scores in 42 and 29 topics in Hindi and Sanskrit languages and reduces in 8 and 15 topics, respectively. The percentage change in the average precision score for each query is shown in Figures 7 and 8. In Sanskrit, some queries provide phenomenal retrieval effectiveness. For example, in Topic 47, BJP party’s national executive meeting held in New Delhi, the decompounding model improves the average precision score by 102.93%. A similar observation is found in Topic 34, corruption in P.N.B. bank (improvement of 86.59%).

Figure 6. A query by query evaluation in the Marathi by In_expC2 model.

Figure 7. A query by query evaluation in the Hindi by In_expC2 model.

Figure 8. A query by query evaluation in the Sanskrit by BB2 model.

11. Discussion

In the first set of experiments, we evaluate the effect of different corpus-based decompounding models (shown in Tables 3, 4, and 5) in Indian language IR. Different corpus-based word-decompounding models are observed to improve the effectiveness of IR systems. Among them, the frequency-based approach provides the poorest effectiveness, while the co-occurrence-based model performs best in terms of Indian language IR. The MAP score improvement in Marathi was 12.94% (the frequency-based approach) and 14.98% (co-occurrence-based approach) here, Ganguly et al. (Reference Ganguly, Leveling and Jones2013) and Monz and Rijke (Reference Monz and Rijke2001) reported that the corpus-based decompounding model improved an MAP score of 2.72% in Bengali, 6.1% in Dutch, and 9.6% in German. In the European language, the frequency-based decompounding approach performs best in German-English machine translation Koehn and Knight (Reference Koehn and Knight2003) but performs poorly in morphologically rich Indian language IR. The fundamental reason is that splitting a compound word based on the frequency of constituent words changes the word’s original meaning in many cases in non-Indian languages. For example, the compound word ‘underworld’ is split into ‘under’ and ‘world’ due to the high-frequency constituents in the collection. Here, the compound splitting is syntactically correct but changes the semantic meaning of the word. Hence, compound splitting potentially reduces the effectiveness of an IR system. The characteristics of the Indian language compound words differ from those of the European ones, so their effectiveness is affected disruptively.

In the second set of experiments, we evaluate the effect of different hybrid machine learning-based decompounding models (shown in Tables 6, 7, and 8) in Indian language IR. We notice that different hybrid machine learning-based models improve effectiveness in Indian language IR. The maximum MAP score gain in a hybrid machine learning-based decompounding model in Marathi is 22.27%. In contrast, the maximum MAP score gained by a corpus-based decompounding model in German is 9.6% Monz and Rijke (Reference Monz and Rijke2001). No particular machine learning-based model performs best in Indian languages. We also observe that the hybrid machine learning-based models outperform the corpus-based models in general. The fundamental reason is that the corpus-based models primarily comprise the dictionary and could not split the sandhi-ed compound word efficiently. But, the hybrid machine learning-based models split both simple concatenation and sandhied compound words better. Hybrid machine learning-based models were also seen to outperform the corpus-based models in Dutch and German IR Monz and Rijke (Reference Monz and Rijke2001).

In the third set of experiments, we evaluate the effect of different deep learning-based decompounding models (shown in Tables 9, 10, and 11) in Indian language IR. We find that different deep learning-based word-decompounding models improve the effectiveness of IR systems even further. In Marathi and Hindi languages, the Bi-LSTM-A and Bi-RNN-A models are seen to perform brilliantly, improving MAP scores by 28.02% and 18.18%, respectively. Similarly, in Sanskrit, the Bi-RNN-A model performs the best and improves an MAP score by 6.1%. The deep learning-based models provide better effectiveness in Marathi compared to Hindi and Sanskrit. The primary reason is that we used here a Marathi dataset particularly developed for a multi-word study by Singh et al. (Reference Singh, Bhingardive and Bhattacharyya2016). b) The number of relevant documents in Sanskrit is less than that of other two languages, as the Sanskrit dataset is the smallest. There are no significant MAP score differences between the vanilla RNN, LSTM, and GRU and their bidirectional counterparts. Among the different deep learning-based models, the attention-based models outperform the other models in different Indian languages. The maximum MAP score gain in any deep learning-based decompounding models in the Marathi is 28.02%, whereas that by a corpus-based decompounding model in German is 9.6% Monz and Rijke (Reference Monz and Rijke2001). Deep learning-based models outperform the corpus-based and hybrid machine learning-based models in Indian languages. The fundamental reasons behind it are (a) deep learning models provide better location and splitting prediction accuracy and (b) Indian languages are morphologically rich and comprise various compound words.

Among the different retrieval models, we notice that the probabilistic models (BM25 and TF-IDF) offer the best MAP scores in Marathi and Hindi. The language model provides moderate effectiveness. Among the DFR-based models (In_expC2, BB2 and InL2), the In_expC2 model provides a low MAP score. In Sanskrit, the language model provides the best MAP score, and the probabilistic models and DFR-based models provide similar MAP scores.

12. Conclusion

Decompounding is an important preprocessing step in the Indian language IR. In this study, we explore three decompounding techniques, i.e., corpus-based, hybrid machine learning-based, and deep learning-based models in different Indian languages IR. The above experiments show that decompounding improves retrieval effectiveness in the IR domain. Among the corpus-based decompounding models, the co-occurrence-based model provides the best MAP score across the Indian languages. Other techniques (frequency-based, maximum branching factor, and tri-based) are not that effective for the Indian languages studied here. We also observe that the corpus-based models provide poor effectiveness compared to other decompounding models. In hybrid machine learning-based models, the CRF model provides the best MAP score in Marathi IR. Similarly, the Random Forest and KNN models outperform the others in Hindi and Sanskrit IR. We observe that the hybrid machine learning-based models outperform the corpus-based models in the Indian language IR. In deep learning-based models, the Bi-LSTM-A model performs best in Marathi IR. Similarly, the bi-RNN-A model outperforms other models in Hindi and Sanskrit IR. Among the different deep learning-based models, the attention-based models outperform the other deep learning-based models in different Indian languages. Moreover, the deep learning-based models outperform the corpus-based and hybrid machine learning-based models in Indian language IR. While evaluating different IR models, we notice that the In_expC2 model provides the best retrieval effectiveness gain in Marathi and Hindi IR. Similarly, the BB2 model is the most effective in Sanskrit IR.

Acknowledgements

This work was supported by IIT (B.H.U), Varanasi. Moreover, the support and the resources provided by PARAM Shivay Facility under the National Supercomputing Mission, Government of India at the IIT (B.H.U), Varanasi, are gratefully acknowledged.

Appendix

Table A.1. List of prefixes used in different Indian languages IR

Footnotes

Special Issue on ‘Natural Language Processing Applications for Low-Resource Languages

b The word Sandhi means placing together.

f The word Sandhi means placing together.

h as described in Ashtadhyayi (azwADyAyI).

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Figure 0

Figure 1. Sandhi-window (AnaNg) as the prediction target in a compound word.

Figure 1

Figure 2. Model architecture for Sandhi Split – Stage 1.

Figure 2

Figure 3. A basic RNN architecture.

Figure 3

Table 1. Show the Parameter of different Encoder–Decoder models

Figure 4

Figure 4. A single cell LSTM architecture.

Figure 5

Figure 5. A single cell GRU architecture.

Figure 6

Table 2. Statistics of text collection

Figure 7

Table 3. MAP scores of different corpus-based decompounding evaluation in Marathi (39 T queries)

Figure 8

Table 4. MAP scores of different corpus-based decompounding evaluation in Hindi (50 T queries)

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Table 5. MAP scores of different corpus-based decompounding evaluation in Sanskrit (50 T queries)

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Table 6. MAP scores of different hybrid machine learning-based decompounding evaluation in the Marathi (39 T queries)

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Table 7. MAP scores of different hybrid machine learning-based decompounding evaluation in the Hindi (50 T queries)

Figure 12

Table 8. MAP scores of different hybrid machine learning-based decompounding evaluation in the Sanskrit (50 T queries)

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Table 9. MAP scores of different deep learning-based decompounding evaluation in the Marathi (39 T queries)

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Table 10. MAP scores of different deep learning-based decompounding evaluation in the Hindi (50 T queries)

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Table 11. MAP scores of different deep learning-based decompounding evaluation in the Sanskrit (50 T queries)

Figure 16

Figure 6. A query by query evaluation in the Marathi by In_expC2 model.

Figure 17

Figure 7. A query by query evaluation in the Hindi by In_expC2 model.

Figure 18

Figure 8. A query by query evaluation in the Sanskrit by BB2 model.

Figure 19

Table A.1. List of prefixes used in different Indian languages IR