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	---
	language: sm
	language_name: Samoan
	language_family: austronesian_polynesian
	tags:
	- wikilangs
	- nlp
	- tokenizer
	- embeddings
	- n-gram
	- markov
	- wikipedia
	- feature-extraction
	- sentence-similarity
	- tokenization
	- n-grams
	- markov-chain
	- text-mining
	- fasttext
	- babelvec
	- vocabulous
	- vocabulary
	- monolingual
	- family-austronesian_polynesian
	license: mit
	library_name: wikilangs
	pipeline_tag: text-generation
	datasets:
	- omarkamali/wikipedia-monthly
	dataset_info:
	name: wikipedia-monthly
	description: Monthly snapshots of Wikipedia articles across 300+ languages
	metrics:
	- name: best_compression_ratio
	type: compression
	value: 3.699
	- name: best_isotropy
	type: isotropy
	value: 0.2278
	- name: vocabulary_size
	type: vocab
	value: 0
	generated: 2026-01-10
	---

	# Samoan - Wikilangs Models
	## Comprehensive Research Report & Full Ablation Study

	This repository contains NLP models trained and evaluated by Wikilangs, specifically on Samoan Wikipedia data.
	We analyze tokenizers, n-gram models, Markov chains, vocabulary statistics, and word embeddings.

	## 📋 Repository Contents

	### Models & Assets

	- Tokenizers (8k, 16k, 32k, 64k)
	- N-gram models (2, 3, 4, 5-gram)
	- Markov chains (context of 1, 2, 3, 4 and 5)
	- Subword N-gram and Markov chains
	- Embeddings in various sizes and dimensions (aligned and unaligned)
	- Language Vocabulary
	- Language Statistics

	![Performance Dashboard](visualizations/performance_dashboard.png)

	### Analysis and Evaluation

	- [1. Tokenizer Evaluation](#1-tokenizer-evaluation)
	- [2. N-gram Model Evaluation](#2-n-gram-model-evaluation)
	- [3. Markov Chain Evaluation](#3-markov-chain-evaluation)
	- [4. Vocabulary Analysis](#4-vocabulary-analysis)
	- [5. Word Embeddings Evaluation](#5-word-embeddings-evaluation)
	- [6. Morphological Analysis (Experimental)](#6--morphological-analysis-experimental)
	- [7. Summary & Recommendations](#7-summary--recommendations)
	- [Metrics Glossary](#appendix-metrics-glossary--interpretation-guide)
	- [Visualizations Index](#visualizations-index)

	---
	## 1. Tokenizer Evaluation

	![Tokenizer Compression](visualizations/tokenizer_compression.png)

	![Tokenizer Fertility](visualizations/tokenizer_fertility.png)

	![Tokenizer OOV](visualizations/tokenizer_oov.png)

	![Total Tokens](visualizations/tokenizer_total_tokens.png)

	### Results

	\| Vocab Size \| Compression \| Avg Token Len \| UNK Rate \| Total Tokens \|
	\|------------\|-------------\|---------------\|----------\|--------------\|
	\| 8k \| 3.479x \| 3.48 \| 0.3471% \| 262,440 \|
	\| 16k \| 3.631x \| 3.63 \| 0.3622% \| 251,487 \|
	\| 32k \| 3.699x 🏆 \| 3.70 \| 0.3691% \| 246,822 \|

	### Tokenization Examples

	Below are sample sentences tokenized with each vocabulary size:

	Sample 1: `Faleu o le motu i Samoa e tu i le va o Upolu ma Savai'i. E 354 tagata e nonofo i...`

	\| Vocab \| Tokens \| Count \|
	\|-------\|--------\|-------\|
	\| 8k \| `▁faleu ▁o ▁le ▁motu ▁i ▁samoa ▁e ▁tu ▁i ▁le ... (+18 more)` \| 28 \|
	\| 16k \| `▁faleu ▁o ▁le ▁motu ▁i ▁samoa ▁e ▁tu ▁i ▁le ... (+18 more)` \| 28 \|
	\| 32k \| `▁faleu ▁o ▁le ▁motu ▁i ▁samoa ▁e ▁tu ▁i ▁le ... (+18 more)` \| 28 \|

	Sample 2: `'O Porirua, 'o se pitonu'u o Ueligitone, e tū i le itū i mātū o Ueligitone. 'O l...`

	\| Vocab \| Tokens \| Count \|
	\|-------\|--------\|-------\|
	\| 8k \| `▁' o ▁po rirua , ▁' o ▁se ▁pitonu ' ... (+35 more)` \| 45 \|
	\| 16k \| `▁' o ▁porirua , ▁' o ▁se ▁pitonu ' u ... (+33 more)` \| 43 \|
	\| 32k \| `▁' o ▁porirua , ▁' o ▁se ▁pitonu ' u ... (+33 more)` \| 43 \|

	Sample 3: `Gagana Urdu o le igoa o se tasi o gagana sili e tautalagia i Asia i Saute. o se ...`

	\| Vocab \| Tokens \| Count \|
	\|-------\|--------\|-------\|
	\| 8k \| `▁gagana ▁u rd u ▁o ▁le ▁igoa ▁o ▁se ▁tasi ... (+19 more)` \| 29 \|
	\| 16k \| `▁gagana ▁urdu ▁o ▁le ▁igoa ▁o ▁se ▁tasi ▁o ▁gagana ... (+17 more)` \| 27 \|
	\| 32k \| `▁gagana ▁urdu ▁o ▁le ▁igoa ▁o ▁se ▁tasi ▁o ▁gagana ... (+17 more)` \| 27 \|


	### Key Findings

	- Best Compression: 32k achieves 3.699x compression
	- Lowest UNK Rate: 8k with 0.3471% unknown tokens
	- Trade-off: Larger vocabularies improve compression but increase model size
	- Recommendation: 32k vocabulary provides optimal balance for production use

	---
	## 2. N-gram Model Evaluation

	![N-gram Perplexity](visualizations/ngram_perplexity.png)

	![N-gram Unique](visualizations/ngram_unique.png)

	![N-gram Coverage](visualizations/ngram_coverage.png)

	### Results

	\| N-gram \| Variant \| Perplexity \| Entropy \| Unique N-grams \| Top-100 Coverage \| Top-1000 Coverage \|
	\|--------\|---------\|------------\|---------\|----------------\|------------------\|-------------------\|
	\| 2-gram \| Word \| 1,420 \| 10.47 \| 5,447 \| 34.7% \| 69.5% \|
	\| 2-gram \| Subword \| 148 🏆 \| 7.21 \| 1,516 \| 82.0% \| 99.6% \|
	\| 3-gram \| Word \| 4,688 \| 12.19 \| 9,293 \| 16.7% \| 49.5% \|
	\| 3-gram \| Subword \| 941 \| 9.88 \| 9,076 \| 43.7% \| 85.0% \|
	\| 4-gram \| Word \| 8,012 \| 12.97 \| 14,168 \| 15.4% \| 36.7% \|
	\| 4-gram \| Subword \| 3,888 \| 11.92 \| 32,524 \| 25.1% \| 60.3% \|
	\| 5-gram \| Word \| 5,147 \| 12.33 \| 8,822 \| 19.7% \| 40.7% \|
	\| 5-gram \| Subword \| 9,558 \| 13.22 \| 54,942 \| 16.3% \| 44.0% \|

	### Top 5 N-grams by Size

	2-grams (Word):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `o le` \| 9,077 \|
	\| 2 \| `i le` \| 5,656 \|
	\| 3 \| `ma le` \| 1,981 \|
	\| 4 \| `o se` \| 1,645 \|
	\| 5 \| `ai le` \| 934 \|

	3-grams (Word):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `le itu i` \| 323 \|
	\| 2 \| `i totonu o` \| 318 \|
	\| 3 \| `le tele o` \| 314 \|
	\| 4 \| `i le itu` \| 292 \|
	\| 5 \| `i le taimi` \| 261 \|

	4-grams (Word):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `i le itu i` \| 270 \|
	\| 2 \| `i totonu o le` \| 162 \|
	\| 3 \| `i luga o le` \| 161 \|
	\| 4 \| `i le taimi o` \| 148 \|
	\| 5 \| `ina ua mavae le` \| 144 \|

	5-grams (Word):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `i le taimi o le` \| 117 \|
	\| 2 \| `le fuainumera o roma e` \| 109 \|
	\| 3 \| `ma le numera i luma` \| 109 \|
	\| 4 \| `i le fuainumera o roma` \| 109 \|
	\| 5 \| `numera ina ua mavae le` \| 109 \|

	2-grams (Subword):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `a _` \| 53,637 \|
	\| 2 \| `e _` \| 43,766 \|
	\| 3 \| `_ l` \| 34,339 \|
	\| 4 \| `l e` \| 32,460 \|
	\| 5 \| `i _` \| 31,222 \|

	3-grams (Subword):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `_ l e` \| 26,576 \|
	\| 2 \| `l e _` \| 26,204 \|
	\| 3 \| `_ o _` \| 19,315 \|
	\| 4 \| `_ m a` \| 14,321 \|
	\| 5 \| `o _ l` \| 11,791 \|

	4-grams (Subword):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `_ l e _` \| 23,778 \|
	\| 2 \| `o _ l e` \| 10,327 \|
	\| 3 \| `_ o _ l` \| 10,137 \|
	\| 4 \| `i _ l e` \| 8,107 \|
	\| 5 \| `a _ o _` \| 6,868 \|

	5-grams (Subword):

	\| Rank \| N-gram \| Count \|
	\|------\|--------\|-------\|
	\| 1 \| `o _ l e _` \| 9,763 \|
	\| 2 \| `_ o _ l e` \| 8,925 \|
	\| 3 \| `i _ l e _` \| 7,577 \|
	\| 4 \| `_ i _ l e` \| 5,715 \|
	\| 5 \| `a _ l e _` \| 4,253 \|


	### Key Findings

	- Best Perplexity: 2-gram (subword) with 148
	- Entropy Trend: Decreases with larger n-grams (more predictable)
	- Coverage: Top-1000 patterns cover ~44% of corpus
	- Recommendation: 4-gram or 5-gram for best predictive performance

	---
	## 3. Markov Chain Evaluation

	![Markov Entropy](visualizations/markov_entropy.png)

	![Markov Contexts](visualizations/markov_contexts.png)

	![Markov Branching](visualizations/markov_branching.png)

	### Results

	\| Context \| Variant \| Avg Entropy \| Perplexity \| Branching Factor \| Unique Contexts \| Predictability \|
	\|---------\|---------\|-------------\|------------\|------------------\|-----------------\|----------------\|
	\| 1 \| Word \| 0.7561 \| 1.689 \| 4.50 \| 15,898 \| 24.4% \|
	\| 1 \| Subword \| 0.7846 \| 1.723 \| 5.33 \| 833 \| 21.5% \|
	\| 2 \| Word \| 0.3231 \| 1.251 \| 1.84 \| 71,107 \| 67.7% \|
	\| 2 \| Subword \| 0.8391 \| 1.789 \| 4.50 \| 4,437 \| 16.1% \|
	\| 3 \| Word \| 0.1599 \| 1.117 \| 1.31 \| 130,468 \| 84.0% \|
	\| 3 \| Subword \| 0.7319 \| 1.661 \| 3.20 \| 19,925 \| 26.8% \|
	\| 4 \| Word \| 0.0696 🏆 \| 1.049 \| 1.11 \| 170,247 \| 93.0% \|
	\| 4 \| Subword \| 0.4868 \| 1.401 \| 2.10 \| 63,588 \| 51.3% \|

	### Generated Text Samples (Word-based)

	Below are text samples generated from each word-based Markov chain model:

	Context Size 1:

	1. `le fasi vaega aai tagata saina iunite setete o le taimi lona tino o se tamaoaiga`
	2. `o le ʻulu taumamao pick the pacific ma talitonuga i le tausaga e mafai ona tagata`
	3. `i comoros ma aganu u ma o se tasi pe nautele e sumpini ma agafesootai faasalalauga`

	Context Size 2:

	1. `o le numera i luma 13 i saint léonard de noblat mau faasino o isi taaloga lauiloa`
	2. `i le i umi a ua o le atunuu i matu ma i ni tausaga o le`
	3. `ma le pulega a siamani sa ina ua maeʻa ona faʻaleaogaina le tulafono lea na faʻatulagaina e`

	Context Size 3:

	1. `le itu i sasae ma vao mago i le ogatotonu ma le taufaaiuiuga o le na faatoilaloina malo`
	2. `i totonu o fale gaosi mea manogi ma le fuala au e a ai iai tagata`
	3. `le tele o malaga militeli i amazonia ma na latou manumalo i au peretania ma holani na faʻatutuina`

	Context Size 4:

	1. `i le itu i matu i le ina ua manumalo ia mehmet ali o le na toe faafoi mai`
	2. `i totonu o le taimi μ 2σ ma le mea e le ai μ o le galuega taua ona`
	3. `i luga o le koluse e pei o le us ma fa atau atu i lapopo a masani po`


	### Generated Text Samples (Subword-based)

	Below are text samples generated from each subword-based Markov chain model:

	Context Size 1:

	1. `_chale_mailaʻa,j`
	2. `aau_me_akma_ta_l`
	3. `ino._ma_ve_o'ita`

	Context Size 2:

	1. `a_se_181_mafa'i_f`
	2. `e_kalosi_e_faʻalo`
	3. `_le_pala,_e_mesei`

	Context Size 3:

	1. `_le_o_featrodriver`
	2. `le_tusitu_o_luga_f`
	3. `_o_le_upu_i_le_lal`

	Context Size 4:

	1. `_le_masani_ma_pi'i_`
	2. `o_le_fa'atatau_e_om`
	3. `_o_le_vaomalo_o_le_`


	### Key Findings

	- Best Predictability: Context-4 (word) with 93.0% predictability
	- Branching Factor: Decreases with context size (more deterministic)
	- Memory Trade-off: Larger contexts require more storage (63,588 contexts)
	- Recommendation: Context-3 or Context-4 for text generation

	---
	## 4. Vocabulary Analysis

	![Zipf's Law](visualizations/zipf_law.png)

	![Top Words](visualizations/top20_words.png)

	![Coverage Curve](visualizations/vocab_coverage.png)

	### Statistics

	\| Metric \| Value \|
	\|--------\|-------\|
	\| Vocabulary Size \| 6,946 \|
	\| Total Tokens \| 205,396 \|
	\| Mean Frequency \| 29.57 \|
	\| Median Frequency \| 4 \|
	\| Frequency Std Dev \| 439.18 \|

	### Most Common Words

	\| Rank \| Word \| Frequency \|
	\|------\|------\|-----------\|
	\| 1 \| le \| 23,989 \|
	\| 2 \| o \| 21,093 \|
	\| 3 \| i \| 12,188 \|
	\| 4 \| e \| 7,623 \|
	\| 5 \| ma \| 6,494 \|
	\| 6 \| ai \| 3,240 \|
	\| 7 \| se \| 2,986 \|
	\| 8 \| fa \| 2,814 \|
	\| 9 \| a \| 2,774 \|
	\| 10 \| na \| 2,325 \|

	### Least Common Words (from vocabulary)

	\| Rank \| Word \| Frequency \|
	\|------\|------\|-----------\|
	\| 1 \| eisleben \| 2 \|
	\| 2 \| magdeburg \| 2 \|
	\| 3 \| halle \| 2 \|
	\| 4 \| saale \| 2 \|
	\| 5 \| 451 \| 2 \|
	\| 6 \| komiunisi \| 2 \|
	\| 7 \| stasi \| 2 \|
	\| 8 \| henryk \| 2 \|
	\| 9 \| dominiak \| 2 \|
	\| 10 \| tychy \| 2 \|

	### Zipf's Law Analysis

	\| Metric \| Value \|
	\|--------\|-------\|
	\| Zipf Coefficient \| 1.1786 \|
	\| R² (Goodness of Fit) \| 0.991320 \|
	\| Adherence Quality \| excellent \|

	### Coverage Analysis

	\| Top N Words \| Coverage \|
	\|-------------\|----------\|
	\| Top 100 \| 63.2% \|
	\| Top 1,000 \| 86.7% \|
	\| Top 5,000 \| 98.1% \|
	\| Top 10,000 \| 0.0% \|

	### Key Findings

	- Zipf Compliance: R²=0.9913 indicates excellent adherence to Zipf's law
	- High Frequency Dominance: Top 100 words cover 63.2% of corpus
	- Long Tail: -3,054 words needed for remaining 100.0% coverage

	---
	## 5. Word Embeddings Evaluation

	![Embedding Isotropy](visualizations/embedding_isotropy.png)

	![Similarity Matrix](visualizations/embedding_similarity.png)

	![t-SNE Words](visualizations/tsne_words.png)

	![t-SNE Sentences](visualizations/tsne_sentences.png)


	### 5.1 Cross-Lingual Alignment

	![Alignment Quality](visualizations/embedding_alignment_quality.png)

	![Multilingual t-SNE](visualizations/embedding_tsne_multilingual.png)


	### 5.2 Model Comparison

	\| Model \| Dimension \| Isotropy \| Semantic Density \| Alignment R@1 \| Alignment R@10 \|
	\|-------\|-----------\|----------\|------------------\|---------------\|----------------\|
	\| mono_32d \| 32 \| 0.2278 🏆 \| 0.4650 \| N/A \| N/A \|
	\| mono_64d \| 64 \| 0.0423 \| 0.4640 \| N/A \| N/A \|
	\| mono_128d \| 128 \| 0.0056 \| 0.4667 \| N/A \| N/A \|
	\| aligned_32d \| 32 \| 0.2278 \| 0.4475 \| 0.0180 \| 0.1140 \|
	\| aligned_64d \| 64 \| 0.0423 \| 0.4740 \| 0.0100 \| 0.1280 \|
	\| aligned_128d \| 128 \| 0.0056 \| 0.4559 \| 0.0100 \| 0.1320 \|

	### Key Findings

	- Best Isotropy: mono_32d with 0.2278 (more uniform distribution)
	- Semantic Density: Average pairwise similarity of 0.4622. Lower values indicate better semantic separation.
	- Alignment Quality: Aligned models achieve up to 1.8% R@1 in cross-lingual retrieval.
	- Recommendation: 128d aligned for best cross-lingual performance

	---
	## 6. Morphological Analysis (Experimental)

	This section presents an automated morphological analysis derived from the statistical divergence between word-level and subword-level models. By analyzing where subword predictability spikes and where word-level coverage fails, we can infer linguistic structures without supervised data.

	### 6.1 Productivity & Complexity

	\| Metric \| Value \| Interpretation \| Recommendation \|
	\|--------\|-------\|----------------\|----------------\|
	\| Productivity Index \| 5.000 \| High morphological productivity \| Reliable analysis \|
	\| Idiomaticity Gap \| -0.073 \| Low formulaic content \| - \|

	### 6.2 Affix Inventory (Productive Units)

	These are the most productive prefixes and suffixes identified by sampling the vocabulary for global substitutability patterns. A unit is considered an affix if stripping it leaves a valid stem that appears in other contexts.

	#### Productive Prefixes
	\| Prefix \| Examples \|
	\|--------\|----------\|
	\| `-a` \| aofaiga, antoine, amaloloina \|
	\| `-t` \| taunuu, tamaloloa, tioata \|
	\| `-s` \| sofia, saita, siaki \|
	\| `-fa` \| faautauta, faatumauina, faamatalaina \|
	\| `-ma` \| macon, mataʻafa, maui \|
	\| `-m` \| macon, mataʻafa, maui \|
	\| `-f` \| faautauta, fetolofi, fuga \|
	\| `-p` \| perth, pa, portuguese \|

	#### Productive Suffixes
	\| Suffix \| Examples \|
	\|--------\|----------\|
	\| `-a` \| faautauta, aofaiga, tamaloloa \|
	\| `-na` \| faatumauina, amaloloina, faamatalaina \|
	\| `-i` \| fetolofi, igilisi, siaki \|
	\| `-ga` \| aofaiga, fuga, aleaga \|
	\| `-e` \| antoine, portuguese, die \|
	\| `-ia` \| sofia, alapenia, omia \|
	\| `-o` \| faalagolago, fono, lafo \|
	\| `-n` \| macon, region, australien \|

	### 6.3 Bound Stems (Lexical Roots)

	Bound stems are high-frequency subword units that are semantically cohesive but rarely appear as standalone words. These often correspond to the 'core' of a word that requires inflection or derivation to be valid.

	\| Stem \| Cohesion \| Substitutability \| Examples \|
	\|------\|----------\|------------------\|----------\|
	\| `faat` \| 1.79x \| 10 contexts \| faatoa, faatau, faatonu \|
	\| `usia` \| 1.48x \| 15 contexts \| lusia, fusia, tusia \|
	\| `aata` \| 1.78x \| 9 contexts \| alaata, faatau, faatasi \|
	\| `alol` \| 1.56x \| 11 contexts \| malolo, malole, palolo \|
	\| `atas` \| 1.46x \| 13 contexts \| atasi, atasia, atassi \|
	\| `amat` \| 1.36x \| 14 contexts \| amata, tamato, mamate \|
	\| `loga` \| 1.51x \| 10 contexts \| iloga, aloga, pologa \|
	\| `aʻat` \| 1.86x \| 6 contexts \| faʻatau, faʻatasi, faʻatusa \|
	\| `atal` \| 1.30x \| 15 contexts \| atali, matala, atalii \|
	\| `faas` \| 1.65x \| 7 contexts \| faasee, faasao, faasoa \|
	\| `tion` \| 1.54x \| 8 contexts \| action, station, section \|
	\| `mafa` \| 1.56x \| 7 contexts \| mafai, mafaia, mamafa \|

	### 6.4 Affix Compatibility (Co-occurrence)

	This table shows which prefixes and suffixes most frequently co-occur on the same stems, revealing the 'stacking' rules of the language's morphology.

	\| Prefix \| Suffix \| Frequency \| Examples \|
	\|--------\|--------\|-----------\|----------\|
	\| `-fa` \| `-a` \| 323 words \| faautauta, faatumauina \|
	\| `-a` \| `-a` \| 202 words \| aofaiga, amaloloina \|
	\| `-t` \| `-a` \| 140 words \| tamaloloa, tioata \|
	\| `-fa` \| `-na` \| 128 words \| faatumauina, faamatalaina \|
	\| `-fa` \| `-ga` \| 104 words \| faʻasinomaga, faʻauʻuga \|
	\| `-s` \| `-a` \| 70 words \| sofia, saita \|
	\| `-a` \| `-na` \| 67 words \| amaloloina, aolaolaina \|
	\| `-fa` \| `-i` \| 61 words \| faafetaui, faamaoti \|
	\| `-f` \| `-a` \| 61 words \| faautauta, fuga \|
	\| `-ma` \| `-a` \| 60 words \| mataʻafa, manatuaina \|

	### 6.5 Recursive Morpheme Segmentation

	Using Recursive Hierarchical Substitutability, we decompose complex words into their constituent morphemes. This approach handles nested affixes (e.g., `prefix-prefix-root-suffix`).

	\| Word \| Suggested Split \| Confidence \| Stem \|
	\|------\|-----------------\|------------\|------\|
	\| faatapulaa \| `faatapul-a-a` \| 7.5 \| `a` \|
	\| mulimulitai \| `mulimuli-ta-i` \| 7.5 \| `ta` \|
	\| television \| `televis-i-on` \| 7.5 \| `i` \|
	\| atinaeina \| `atinae-i-na` \| 7.5 \| `i` \|
	\| faatulaga \| `fa-a-tulaga` \| 7.5 \| `tulaga` \|
	\| faʻamoemoeina \| `faʻamoemoe-i-na` \| 7.5 \| `i` \|
	\| faataunuuina \| `faataunuu-i-na` \| 7.5 \| `i` \|
	\| felagolagomai \| `felagolagom-a-i` \| 7.5 \| `a` \|
	\| mataituina \| `mataitu-i-na` \| 7.5 \| `i` \|
	\| faatosina \| `faato-si-na` \| 7.5 \| `si` \|
	\| faaitulagi \| `fa-a-itulagi` \| 7.5 \| `itulagi` \|
	\| limasefulu \| `li-ma-sefulu` \| 7.5 \| `sefulu` \|
	\| faʻatulaga \| `faʻatul-a-ga` \| 7.5 \| `a` \|
	\| fonotatalo \| `fonotat-a-lo` \| 7.5 \| `a` \|
	\| vaʻavaʻaia \| `vaʻavaʻ-a-ia` \| 7.5 \| `a` \|

	### 6.6 Linguistic Interpretation

	> Automated Insight:
	The language Samoan shows high morphological productivity. The subword models are significantly more efficient than word models, suggesting a rich system of affixation or compounding.

	---
	## 7. Summary & Recommendations

	![Performance Dashboard](visualizations/performance_dashboard.png)

	### Production Recommendations

	\| Component \| Recommended \| Rationale \|
	\|-----------\|-------------\|-----------\|
	\| Tokenizer \| 32k BPE \| Best compression (3.70x) \|
	\| N-gram \| 2-gram \| Lowest perplexity (148) \|
	\| Markov \| Context-4 \| Highest predictability (93.0%) \|
	\| Embeddings \| 100d \| Balanced semantic capture and isotropy \|


	---
	## Appendix: Metrics Glossary & Interpretation Guide

	This section provides definitions, intuitions, and guidance for interpreting the metrics used throughout this report.

	### Tokenizer Metrics

	Compression Ratio
	> Definition: The ratio of characters to tokens (chars/token). Measures how efficiently the tokenizer represents text.
	>
	> Intuition: Higher compression means fewer tokens needed to represent the same text, reducing sequence lengths for downstream models. A 3x compression means ~3 characters per token on average.
	>
	> What to seek: Higher is generally better for efficiency, but extremely high compression may indicate overly aggressive merging that loses morphological information.

	Average Token Length (Fertility)
	> Definition: Mean number of characters per token produced by the tokenizer.
	>
	> Intuition: Reflects the granularity of tokenization. Longer tokens capture more context but may struggle with rare words; shorter tokens are more flexible but increase sequence length.
	>
	> What to seek: Balance between 2-5 characters for most languages. Arabic/morphologically-rich languages may benefit from slightly longer tokens.

	Unknown Token Rate (OOV Rate)
	> Definition: Percentage of tokens that map to the unknown/UNK token, indicating words the tokenizer cannot represent.
	>
	> Intuition: Lower OOV means better vocabulary coverage. High OOV indicates the tokenizer encounters many unseen character sequences.
	>
	> What to seek: Below 1% is excellent; below 5% is acceptable. BPE tokenizers typically achieve very low OOV due to subword fallback.

	### N-gram Model Metrics

	Perplexity
	> Definition: Measures how "surprised" the model is by test data. Mathematically: 2^(cross-entropy). Lower values indicate better prediction.
	>
	> Intuition: If perplexity is 100, the model is as uncertain as if choosing uniformly among 100 options at each step. A perplexity of 10 means effectively choosing among 10 equally likely options.
	>
	> What to seek: Lower is better. Perplexity decreases with larger n-grams (more context). Values vary widely by language and corpus size.

	Entropy
	> Definition: Average information content (in bits) needed to encode the next token given the context. Related to perplexity: perplexity = 2^entropy.
	>
	> Intuition: High entropy means high uncertainty/randomness; low entropy means predictable patterns. Natural language typically has entropy between 1-4 bits per character.
	>
	> What to seek: Lower entropy indicates more predictable text patterns. Entropy should decrease as n-gram size increases.

	Coverage (Top-K)
	> Definition: Percentage of corpus occurrences explained by the top K most frequent n-grams.
	>
	> Intuition: High coverage with few patterns indicates repetitive/formulaic text; low coverage suggests diverse vocabulary usage.
	>
	> What to seek: Depends on use case. For language modeling, moderate coverage (40-60% with top-1000) is typical for natural text.

	### Markov Chain Metrics

	Average Entropy
	> Definition: Mean entropy across all contexts, measuring average uncertainty in next-word prediction.
	>
	> Intuition: Lower entropy means the model is more confident about what comes next. Context-1 has high entropy (many possible next words); Context-4 has low entropy (few likely continuations).
	>
	> What to seek: Decreasing entropy with larger context sizes. Very low entropy (<0.1) indicates highly deterministic transitions.

	Branching Factor
	> Definition: Average number of unique next tokens observed for each context.
	>
	> Intuition: High branching = many possible continuations (flexible but uncertain); low branching = few options (predictable but potentially repetitive).
	>
	> What to seek: Branching factor should decrease with context size. Values near 1.0 indicate nearly deterministic chains.

	Predictability
	> Definition: Derived metric: (1 - normalized_entropy) × 100%. Indicates how deterministic the model's predictions are.
	>
	> Intuition: 100% predictability means the next word is always certain; 0% means completely random. Real text falls between these extremes.
	>
	> What to seek: Higher predictability for text generation quality, but too high (>98%) may produce repetitive output.

	### Vocabulary & Zipf's Law Metrics

	Zipf's Coefficient
	> Definition: The slope of the log-log plot of word frequency vs. rank. Zipf's law predicts this should be approximately -1.
	>
	> Intuition: A coefficient near -1 indicates the corpus follows natural language patterns where a few words are very common and most words are rare.
	>
	> What to seek: Values between -0.8 and -1.2 indicate healthy natural language distribution. Deviations may suggest domain-specific or artificial text.

	R² (Coefficient of Determination)
	> Definition: Measures how well the linear fit explains the frequency-rank relationship. Ranges from 0 to 1.
	>
	> Intuition: R² near 1.0 means the data closely follows Zipf's law; lower values indicate deviation from expected word frequency patterns.
	>
	> What to seek: R² > 0.95 is excellent; > 0.99 indicates near-perfect Zipf adherence typical of large natural corpora.

	Vocabulary Coverage
	> Definition: Cumulative percentage of corpus tokens accounted for by the top N words.
	>
	> Intuition: Shows how concentrated word usage is. If top-100 words cover 50% of text, the corpus relies heavily on common words.
	>
	> What to seek: Top-100 covering 30-50% is typical. Higher coverage indicates more repetitive text; lower suggests richer vocabulary.

	### Word Embedding Metrics

	Isotropy
	> Definition: Measures how uniformly distributed vectors are in the embedding space. Computed as the ratio of minimum to maximum singular values.
	>
	> Intuition: High isotropy (near 1.0) means vectors spread evenly in all directions; low isotropy means vectors cluster in certain directions, reducing expressiveness.
	>
	> What to seek: Higher isotropy generally indicates better-quality embeddings. Values > 0.1 are reasonable; > 0.3 is good. Lower-dimensional embeddings tend to have higher isotropy.

	Average Norm
	> Definition: Mean magnitude (L2 norm) of word vectors in the embedding space.
	>
	> Intuition: Indicates the typical "length" of vectors. Consistent norms suggest stable training; high variance may indicate some words are undertrained.
	>
	> What to seek: Relatively consistent norms across models. The absolute value matters less than consistency (low std deviation).

	Cosine Similarity
	> Definition: Measures angular similarity between vectors, ranging from -1 (opposite) to 1 (identical direction).
	>
	> Intuition: Words with similar meanings should have high cosine similarity. This is the standard metric for semantic relatedness in embeddings.
	>
	> What to seek: Semantically related words should score > 0.5; unrelated words should be near 0. Synonyms often score > 0.7.

	t-SNE Visualization
	> Definition: t-Distributed Stochastic Neighbor Embedding - a dimensionality reduction technique that preserves local structure for visualization.
	>
	> Intuition: Clusters in t-SNE plots indicate groups of semantically related words. Spread indicates vocabulary diversity; tight clusters suggest semantic coherence.
	>
	> What to seek: Meaningful clusters (e.g., numbers together, verbs together). Avoid over-interpreting distances - t-SNE preserves local, not global, structure.

	### General Interpretation Guidelines

	1. Compare within model families: Metrics are most meaningful when comparing models of the same type (e.g., 8k vs 64k tokenizer).
	2. Consider trade-offs: Better performance on one metric often comes at the cost of another (e.g., compression vs. OOV rate).
	3. Context matters: Optimal values depend on downstream tasks. Text generation may prioritize different metrics than classification.
	4. Corpus influence: All metrics are influenced by corpus characteristics. Wikipedia text differs from social media or literature.
	5. Language-specific patterns: Morphologically rich languages (like Arabic) may show different optimal ranges than analytic languages.


	### Visualizations Index

	\| Visualization \| Description \|
	\|---------------\|-------------\|
	\| Tokenizer Compression \| Compression ratios by vocabulary size \|
	\| Tokenizer Fertility \| Average token length by vocabulary \|
	\| Tokenizer OOV \| Unknown token rates \|
	\| Tokenizer Total Tokens \| Total tokens by vocabulary \|
	\| N-gram Perplexity \| Perplexity by n-gram size \|
	\| N-gram Entropy \| Entropy by n-gram size \|
	\| N-gram Coverage \| Top pattern coverage \|
	\| N-gram Unique \| Unique n-gram counts \|
	\| Markov Entropy \| Entropy by context size \|
	\| Markov Branching \| Branching factor by context \|
	\| Markov Contexts \| Unique context counts \|
	\| Zipf's Law \| Frequency-rank distribution with fit \|
	\| Vocab Frequency \| Word frequency distribution \|
	\| Top 20 Words \| Most frequent words \|
	\| Vocab Coverage \| Cumulative coverage curve \|
	\| Embedding Isotropy \| Vector space uniformity \|
	\| Embedding Norms \| Vector magnitude distribution \|
	\| Embedding Similarity \| Word similarity heatmap \|
	\| Nearest Neighbors \| Similar words for key terms \|
	\| t-SNE Words \| 2D word embedding visualization \|
	\| t-SNE Sentences \| 2D sentence embedding visualization \|
	\| Position Encoding \| Encoding method comparison \|
	\| Model Sizes \| Storage requirements \|
	\| Performance Dashboard \| Comprehensive performance overview \|

	---
	## About This Project

	### Data Source

	Models trained on [wikipedia-monthly](https://huggingface.co/datasets/omarkamali/wikipedia-monthly) - a monthly snapshot of Wikipedia articles across 300+ languages.

	### Project

	A project by [Wikilangs](https://wikilangs.org) - Open-source NLP models for every Wikipedia language.

	### Maintainer

	[Omar Kamali](https://omarkamali.com) - [Omneity Labs](https://omneitylabs.com)

	### Citation

	If you use these models in your research, please cite:

	```bibtex
	@misc{wikilangs2025,
	author = {Kamali, Omar},
	title = {Wikilangs: Open NLP Models for Wikipedia Languages},
	year = {2025},
	doi = {10.5281/zenodo.18073153},
	publisher = {Zenodo},
	url = {https://huggingface.co/wikilangs}
	institution = {Omneity Labs}
	}
	```

	### License

	MIT License - Free for academic and commercial use.

	### Links

	- 🌐 Website: [wikilangs.org](https://wikilangs.org)
	- 🤗 Models: [huggingface.co/wikilangs](https://huggingface.co/wikilangs)
	- 📊 Data: [wikipedia-monthly](https://huggingface.co/datasets/omarkamali/wikipedia-monthly)
	- 👤 Author: [Omar Kamali](https://huggingface.co/omarkamali)
	- 🤝 Sponsor: [Featherless AI](https://featherless.ai)
	---
	Generated by Wikilangs Models Pipeline

	Report Date: 2026-01-10 21:21:35