Calculate the lexical diversity of text(s).
textstat_lexdiv(x, measure = c("TTR", "C", "R", "CTTR", "U", "S", "K",
"D", "Vm", "Maas", "MATTR", "MSTTR", "all"), remove_numbers = TRUE,
remove_punct = TRUE, remove_symbols = TRUE, remove_hyphens = FALSE,
log.base = 10, MATTR_window = 100L, MSTTR_segment = 100L, ...)
a character vector defining the measure to compute
logical; if TRUE
remove features or tokens that
consist only of numerals (the Unicode "Number" [N] class)
logical; if TRUE
remove all features or tokens
that consist only of the Unicode "Punctuation" [P] class)
logical; if TRUE
remove all features or tokens
that consist only of the Unicode "Punctuation" [S] class)
logical; if TRUE
split words that are connected
by hyphenation and hyphenation-like characters in between words, e.g.
"self-storage" becomes two features or tokens "self" and "storage". Default
is FALSE to preserve such words as is, with the hyphens.
a numeric value defining the base of the logarithm (for measures using logarithms)
a numeric value defining the size of the moving window for computation of the Moving-Average Type-Token Ratio (Covington & McFall, 2010)
a numeric value defining the size of the each segment for the computation of the the Mean Segmental Type-Token Ratio (Johnson, 1944)
for passing arguments to other methods
A data.frame of documents and their lexical diversity scores.
textstat_lexdiv
calculates the lexical diversity of documents
using a variety of indices.
In the following formulas, \(N\) refers to the total number of tokens, \(V\) to the number of types, and \(f_v(i, N)\) to the numbers of types occurring \(i\) times in a sample of length \(N\).
"TTR"
:The ordinary Type-Token Ratio: $$TTR = \frac{V}{N}$$
"C"
:Herdan's C (Herdan, 1960, as cited in Tweedie & Baayen, 1998; sometimes referred to as LogTTR): $$C = \frac{\log{V}}{\log{N}}$$
"R"
:Guiraud's Root TTR (Guiraud, 1954, as cited in Tweedie & Baayen, 1998): $$R = \frac{V}{\sqrt{N}}$$
"CTTR"
:Carroll's Corrected TTR: $$CTTR = \frac{V}{\sqrt{2N}}$$
"U"
:Dugast's Uber Index (Dugast, 1978, as cited in Tweedie & Baayen, 1998): $$U = \frac{(\log{N})^2}{\log{N} - \log{V}}$$
"S"
:Summer's index: $$S = \frac{\log{\log{V}}}{\log{\log{N}}}$$
"K"
:Yule's K (Yule, 1944, as presented in Tweedie & Baayen, 1998, Eq. 16) is calculated by: $$K = 10^4 \times \left[ -\frac{1}{N} + \sum_{i=1}^{V} f_v(i, N) \left( \frac{i}{N} \right)^2 \right] $$
"D"
:Simpson's D (Simpson 1949, as presented in Tweedie & Baayen, 1998, Eq. 17) is calculated by: $$D = \sum_{i=1}^{V} f_v(i, N) \frac{i}{N} \frac{i-1}{N-1}$$
"Vm"
:Herdan's \(V_m\) (Herdan 1955, as presented in Tweedie & Baayen, 1998, Eq. 18) is calculated by: $$V_m = \sqrt{ \sum_{i=1}^{V} f_v(i, N) (i/N)^2 - \frac{i}{V} }$$
"Maas"
:Maas' indices (\(a\), \(\log{V_0}\) & \(\log{}_{e}{V_0}\)): $$a^2 = \frac{\log{N} - \log{V}}{\log{N}^2}$$ $$\log{V_0} = \frac{\log{V}}{\sqrt{1 - \frac{\log{V}}{\log{N}}^2}}$$ The measure was derived from a formula by Mueller (1969, as cited in Maas, 1972). \(\log{}_{e}{V_0}\) is equivalent to \(\log{V_0}\), only with \(e\) as the base for the logarithms. Also calculated are \(a\), \(\log{V_0}\) (both not the same as before) and \(V'\) as measures of relative vocabulary growth while the text progresses. To calculate these measures, the first half of the text and the full text will be examined (see Maas, 1972, p. 67 ff. for details). Note: for the current method (for a dfm) there is no computation on separate halves of the text.
"MATTR"
:The Moving-Average Type-Token Ratio (Covington & McFall, 2010) calculates TTRs for a moving window of tokens from the first to the last token, computing a TTR for each window. The MATTR is the mean of the TTRs of each window.
"MSTTR"
:Mean Segmental Type-Token Ratio (sometimes referred to as Split TTR) splits the tokens into segments of the given size, TTR for each segment is calculated and the mean of these values returned. When this value is < 1.0, it splits the tokens into equal, non-overlapping sections of that size. When this value is > 1, it defines the segments as windows of that size. Tokens at the end which do not make a full segment are ignored.
Covington, M.A. & McFall, J.D. (2010). Cutting the Gordian Knot: The Moving-Average Type-Token Ratio (MATTR). Journal of Quantitative Linguistics, 17(2), 94--100.
Herdan, G. (1955). A New Derivation and Interpretation of Yule's 'Characteristic' K. Zeitschrift f<U+00FC>r angewandte Mathematik und Physik, 6(4): 332--334.
Maas, H.D. (1972). <U+00DC>ber den Zusammenhang zwischen Wortschatzumfang und L<U+00E4>nge eines Textes. Zeitschrift f<U+00FC>r Literaturwissenschaft und Linguistik, 2(8), 73--96.
McCarthy, P.M. & Jarvis, S. (2007). vocd: A Theoretical and Empirical Evaluation. Language Testing, 24(4), 459--488.
McCarthy, P.M. & Jarvis, S. (2010). MTLD, vocd-D, and HD-D: A Validation Study of Sophisticated Approaches to Lexical Diversity Assessment. Behaviour Research Methods, 42(2), 381--392.
Michalke, M. (2014) koRpus: An R Package for Text Analysis. R package version 0.05-5. http://reaktanz.de/?c=hacking&s=koRpus
Simpson, E.H. (1949). Measurement of Diversity. Nature, 163: 688.
Tweedie. F.J. and Baayen, R.H. (1998). How Variable May a Constant Be? Measures of Lexical Richness in Perspective. Computers and the Humanities, 32(5), 323--352.
# NOT RUN {
txt <- c("Anyway, like I was sayin', shrimp is the fruit of the sea. You can
barbecue it, boil it, broil it, bake it, saute it.",
"There's shrimp-kabobs,
shrimp creole, shrimp gumbo. Pan fried, deep fried, stir-fried. There's
pineapple shrimp, lemon shrimp, coconut shrimp, pepper shrimp, shrimp soup,
shrimp stew, shrimp salad, shrimp and potatoes, shrimp burger, shrimp
sandwich.")
tokens(txt) %>%
textstat_lexdiv(measure = c("TTR", "CTTR", "K"))
dfm(txt) %>%
textstat_lexdiv(measure = c("TTR", "CTTR", "K"))
toks <- tokens(corpus_subset(data_corpus_inaugural, Year > 2000))
textstat_lexdiv(toks, c("CTTR", "TTR", "MATTR"), MATTR_window = 100)
# }
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