Simulating language-specific and language-general effects in a statistical learning model of Chinese reading

Yang, Jianfeng; McCandliss, Bruce D.; Shu, Hua; Zevin, Jason D.

doi:10.1016/j.jml.2009.05.001

Cited by 113 publications

(151 citation statements)

References 73 publications

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“…The consistency score, defined by type, is a measure of the total number of friends to the total number of neighbors. Similar to the findings in English, several studies have shown consistency effects in naming Chinese characters (Fang et al, 1986;Hue, 1992;Yang, McCandliss, Shu, & Zevin, 2009). However, these studies have been inconsistent as to whether the consistency effect emerged in naming high-frequency characters.…”

supporting

confidence: 62%

“…Character frequency A considerable amount of evidence has indicated that character frequency is a powerful predictor of RTs in Chinese character recognition; frequency effects have been observed consistently in a wide range of tasks (Hue, 1992;Lee et al, 2005;Liu et al, 2007;Yang et al, 2009). Higher frequency characters tend to be processed more quickly than lower frequency characters during naming (Lee et al, 2005;Yang et al, 2009).…”

Section: Lexical Variablesmentioning

confidence: 99%

“…Higher frequency characters tend to be processed more quickly than lower frequency characters during naming (Lee et al, 2005;Yang et al, 2009). In the present study, the character frequency data was compiled from the ASBC (Huang & Chen, 1998).…”

Section: Lexical Variablesmentioning

confidence: 99%

“…In addition, behavioral naming RTs are provided to substantiate the variables. To further assess the database and demonstrate the importance of selecting ranges of lexical variables, additional multiple regression analyses were conducted to explore the effects of consistency and character frequency (Lee et al, 2005;Yang et al, 2009). The resulting database will be useful for researchers in the area of Chinese language processing, Chinese educators, or linguists interested in conducting cross-linguistic comparisons.…”

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confidence: 99%

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A psycholinguistic database for traditional Chinese character naming

et al. 2015

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In this study, we aimed to provide a large-scale set of psycholinguistic norms for 3,314 traditional Chinese characters, along with their naming reaction times (RTs), collected from 140 Chinese speakers. The lexical and semantic variables in the database include frequency, regularity, familiarity, consistency, number of strokes, homophone density, semantic ambiguity rating, phonetic combinability, semantic combinability, and the number of disyllabic compound words formed by a character. Multiple regression analyses were conducted to examine the predictive powers of these variables for the naming RTs. The results demonstrated that these variables could account for a significant portion of variance (55.8 %) in the naming RTs. An additional multiple regression analysis was conducted to demonstrate the effects of consistency and character frequency. Overall, the regression results were consistent with the findings of previous studies on Chinese character naming. This database should be useful for research into Chinese language processing, Chinese education, or crosslinguistic comparisons. The database can be accessed via an online inquiry system (http://ball.ling.sinica.edu.tw/ namingdatabase/index.html).Keywords Naming . Chinese character naming . Psycholinguistic norm . Chinese visual word recognition Understanding how readers process words, which are fundamental units for reading, has been a core issue in psycholinguistic studies. Behavioral studies have utilized tasks such as naming, lexical decision, speech perception, and synonym judgment, with the aim of understanding how orthographic, phonological, and semantic information is processed during visual word recognition. These experiments have typically employed a factorial design by manipulating one or two lexical variables (e.g., word frequency and spelling-to-sound consistency) in a limited set of stimuli, while trying to control for other lexical variables (e.g., orthographic neighborhood size and acoustic properties of onsets) in order to prevent any potential confounds. Although this approach has provided fruitful evidence to advance our understanding of how various lexical properties affect visual word recognition, it has some limitations in terms of how to select a set of items that vary in only one dimension and how to generalize the findings to a larger set of stimuli.To overcome these limitations, a number of large-scale psycholinguistic databases have been made available for languages with alphabetic orthographies, including English (Balota et al

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supporting

confidence: 62%

Section: Lexical Variablesmentioning

confidence: 99%

Section: Lexical Variablesmentioning

confidence: 99%

mentioning

confidence: 99%

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A psycholinguistic database for traditional Chinese character naming

et al. 2015

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“…For instance, previous models of reading acquisition have made important contributions demonstrating an influence of orthographic transparency on phonological processing (Harm & Seidenberg, 1999;Yang, McCandliss, Shu, & Zevin, 2009) and semantic processing (Harm & Seidenberg, 2004;Yang, Shu, McCandliss, & Zevin, 2013). However, such models have tended to be trained on prototypical phonological representations in which substantial phonological structure is embedded, and then the processing of the phonological structure itself is investigated as both the input and output system.…”

Section: Discussionmentioning

confidence: 99%

Literacy effects on language and vision: Emergent effects from an amodal shared resource (ASR) computational model

Smith

Monaghan

Huettig

2014

Cognitive Psychology

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a b s t r a c tLearning to read and write requires an individual to connect additional orthographic representations to pre-existing mappings between phonological and semantic representations of words. Past empirical results suggest that the process of learning to read and write (at least in alphabetic languages) elicits changes in the language processing system, by either increasing the cognitive efficiency of mapping between representations associated with a word, or by changing the granularity of phonological processing of spoken language, or through a combination of both. Behavioural effects of literacy have typically been assessed in offline explicit tasks that have addressed only phonological processing. However, a recent eye tracking study compared high and low literate participants on effects of phonology and semantics in processing measured implicitly using eye movements. High literates' eye movements were more affected by phonological overlap in online speech than low literates, with only subtle differences observed in semantics. We determined whether these effects were due to cognitive efficiency and/or granularity of speech processing in a multimodal model of speech processing -the amodal shared resource model (ASR, Smith, Monaghan, & Huettig, 2013a,b). We found that cognitive efficiency in the model had only a marginal effect on semantic processing and did not affect performance for phonological processing, whereas fine-grained versus coarse-grained

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Orthography, Word Recognition, and Reading

Braze

Gong

2017

The Handbook of Psycholinguistics

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Orthographies differ from one another in terms of their scripts and in the specifics of the mapping from script to linguistic unit. Orthographic depth, the complexity of the mapping from script to language, modulates the ease with which an orthography is learned. Within an orthography, the consistency or regularity of a particular spelling pattern will temper the difficulty with which written words containing that pattern can be recognized. There is hope for a unified cross-orthography account of visual word recognition, although details of how non-alphabetic writing systems (e.g., syllabaries, morphosyllabaries, alphasyllabaries) may be fit into theoretical frameworks built on a foundation of empirical work on alphabetic reading are not entirely clear. There is a substantial gap in the literature with regard to reading and literacy in languages that make use of non-alphabetic writing systems. This euro-centric bias in reading research continues to limit advances in our understanding of the potential for literacy as a universal human capacity.Keywords: eye movements; computational models; lexical access; lexical representation; orthography; phonology; reading; writing systems PreliminariesThe nature of connection between oral and written language has been worried over by researchers for decades, perhaps as much as a century (Huey, 1908). Huey credits V. Egger with the notion that "to read is, in effect, to translate writing into speech (Huey, 1908, p. 123)." Some 60 years later, this basic idea was well on its way to becoming a lynch pin of our modern understanding of the relationship between speech perception, printed word recognition and language comprehension. Alvin Liberman, in Kavanagh (1968), framed the idea somewhat differently when he wrote that "reading is in some sense

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Simulating language-specific and language-general effects in a statistical learning model of Chinese reading

Cited by 113 publications

References 73 publications

A psycholinguistic database for traditional Chinese character naming

A psycholinguistic database for traditional Chinese character naming

Literacy effects on language and vision: Emergent effects from an amodal shared resource (ASR) computational model

Orthography, Word Recognition, and Reading

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