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Undecimal

Undecimal, also known as the or unodecimal, is a positional numeral system that uses eleven as its , allowing numbers to be represented through powers of 11 with eleven distinct digits typically denoted as 0 through 9 and an additional symbol—often "A" or "T"—to represent the value ten. While undecimal has no documented widespread adoption in any historical culture as a primary counting method, early anthropological reports erroneously suggested its use among the of and the Pañgwa of , claims later attributed to cultural misunderstandings and linguistic misinterpretations rather than actual base-11 systems. In the late , during efforts to reform weights and measures, mathematician ironically advocated for a base-11 system to underscore the practical advantages of decimal arithmetic, arguing that a prime base like 11 would complicate fractions by requiring a common denominator for all unlike units—thus helping to solidify the choice of base 10 for the . In contemporary and , undecimal serves primarily as a theoretical construct to demonstrate properties of non-decimal bases, such as in examples or error-detection algorithms like the ISBN-10 , which employs modulo-11 calculations equivalent to base-11 operations. Its digits extend beyond standard notation, requiring custom symbols for the eleventh position, and conversions between undecimal and decimal involve multiplying each digit by the appropriate power of 11.

Fundamentals

Definition and Positional Notation

Undecimal, also known as base-11, is a that represents numbers using eleven as the base, requiring eleven distinct to denote values from to 10. In this system, the of each determines its contribution to the total value, with the rightmost representing the units place (11^0) and each subsequent to the left corresponding to successively higher powers of 11 (11^1, 11^2, and so on). The value of an undecimal number d_n d_{n-1} \dots d_1 d_0_{11}, where each d_i is a from to 10, is calculated as the sum \sum_{i=0}^{n} d_i \cdot 11^i. This formula generalizes the for any b, adapted here with b = 11, ensuring that the system's structure allows for unique representation of all non-negative integers without ambiguity. To convert a decimal number to undecimal, apply the repeated : divide the number by 11, record the as the least significant , then repeat the process with the quotient until the quotient is zero; the remainders, read from last to first, form the undecimal representation. Conversely, to convert an undecimal number to decimal, evaluate the positional using the above. For example, the number 11 converts to undecimal as follows: 11 ÷ 11 = 1 0; then 1 ÷ 11 = 0 1, yielding 10_{11} (since $1 \cdot 11^1 + 0 \cdot 11^0 = 11). Similarly, 121 in is 100_{11}, as $1 \cdot 11^2 + 0 \cdot 11^1 + 0 \cdot 11^0 = 121.

Digit Symbols and Conventions

In the undecimal (base-11) numeral system, the digits 0 through 9 are represented using the same symbols as in the system, while the eleventh , denoting the value 10, requires an additional due to the limitations of the standard digits. There is no universally adopted standard for this extra , leading to various conventions that prioritize readability, historical precedent, or compatibility with existing systems. Common modern representations for the digit 10 include the letter "A", borrowed from notation where it similarly stands for 10, ensuring familiarity in contexts. Other popular choices are "T" (short for "ten") or "X" (evoking the Roman numeral for ten), both of which are alphabetic and mnemonic. Historically, in the mid-19th century, shorthand expert Isaac Jacob Pitman proposed the turned digit two (↊, U+218A) as a dedicated symbol for 10 in the system; this glyph, resembling a rotated "2", has been adapted in discussions of other higher-base systems like undecimal for its visual distinction from standard digits while maintaining a numeric aesthetic. Variant conventions extend to bijective undecimal systems, which omit the zero digit entirely to create a one-to-one mapping between numbers and digit strings, using 11 distinct symbols typically ranging from 1 to some representation of 11 (often adapting the above choices for the higher values). In practice, uppercase letters like "A" or "T" are preferred over lowercase to avoid confusion with numerals (e.g., "a" resembling "α" or other characters), and symbols are selected to minimize —such as steering clear of "O" for zero in any mixed contexts, though the standard "0" is unambiguous. These choices ultimately depend on the application, with alphabetic symbols favored in programming for their ASCII compatibility and turned digits in mathematical or historical discussions for their uniqueness.

Historical Context

Proposal During the French Revolution

During the (1789–1799), the was commissioned by the to develop a universal system of measurement to standardize the disparate units used across and promote rational, decimal-based reforms. As part of these deliberations in the early 1790s, various numeral bases were considered, including (base 12) for its divisor properties, but the committee ultimately favored base 10. A committee of the Academy, including mathematicians , , and , evaluated these options and advocated for a system, aligning with human —specifically the ten fingers—and established familiarity in counting and . , as a key member, advocated strongly for , arguing against alternatives like base 12 to preserve continuity in existing practices and avoid complications in . These discussions culminated in the adoption of the metric system on April 7, 1795 (18 Germinal, Year III), establishing the and as foundational units, with definitive legalization in 1799. The choice of underscored the priority of practicality over other theoretical bases, laying the groundwork for the (SI).

Alleged Use by the

In the early , French explorers René-Primevère and Poret de Blosseville, during the circumnavigational voyage of the Coquille, published accounts suggesting that the of employed an undecimal counting system. Their observations, detailed in voyage narratives, interpreted Māori terms as indicating a base-11 structure, possibly due to limited interaction or deliberate fabrication, though the exact basis remains unclear. This notion gained further traction through missionary William Williams' 1844 Dictionary of the New Zealand Language, where he described counting practices in a way that implied an undecimal , particularly in rendering numbers beyond ten. Williams' interpretation stemmed from early encounters, but he later revised his views in subsequent editions to align with a system. By the late , mathematician Levi Leonard Conant referenced these sources in his 1896 book The Number Concept: Its Origin and Development, citing the as an example of a society purportedly using 11, thereby perpetuating the claim in academic discourse. The alleged undecimal system hinged on a linguistic misunderstanding of terms like tekau mā tahi, which explorers and early ethnographers took to mean "eleven" as the first number in a new cycle, suggesting 11 as the base. In reality, tekau denotes ten—derived from a tallying practice of grouping items in , often visualized as pairs of five—and mā tahi means "plus one," confirming a standard structure. Contemporary scholarship regards these 19th-century assertions as products of colonial-era ethnographic errors, with no verifiable of true undecimal counting among the . numeration has been consistently documented as , incorporating practical tally methods for grouping, and the base-11 idea reflects broader challenges in numerical interpretation during early European contact.

Alleged Use by the Pañgwa

In the early , Northcote W. Thomas reported an alleged undecimal among the Pañgwa people of , northeast of Lake Nyasa, based on limited ethnographic observations. He described it as an "abnormal numeral system" using a base of eleven, distinct from the predominant systems in . Similarly, colonial administrator and linguist Harry H. Johnston documented a base-11 vocabulary for Pañgwa in his comparative study of , citing terms such as ki-dzigo for eleven, which served as a multiplier for higher numbers like ki-dzigo-kavili (22, or "two elevens") and ki-dzigo-kadatu (33, or "three elevens"). These claims drew from sparse fieldwork data collected around , interpreting unique lexical forms as evidence of an undecimal structure rather than variations within a . However, these assertions stemmed from misinterpretations of the Pañgwa decimal system, which had been influenced by trade interactions introducing Arabic-derived terms; in reality, counting relied on a base-10 system augmented by body-part tallying methods common in East African communities. Later analysis revealed that terms like ki-dzigo likely denoted ten or a related concept, not eleven, with higher counts formed additively rather than multiplicatively in base-11. Post-1950s linguistic studies, including sociolinguistic surveys and grammatical descriptions of Pañgwa (a G.64 spoken by approximately 200,000 people in southwestern as of 2024), have consistently confirmed a standard base, attributing the early undecimal claims to incomplete during colonial-era expeditions. No subsequent attestations support base-11 usage, and the system's orthodox roots—such as -tatu for three and -kumi for ten—align with regional patterns. This case parallels interpretive errors in reports of non- systems elsewhere but is distinctive to the East Bantu context, where Swahili-mediated trade amplified superficial lexical anomalies without altering the underlying decimal structure. Pañgwa also employed pair-counting practices for certain , akin to those in other regions, though this did not indicate a shift to undecimal reckoning.

Modern Applications

In Computing and Systems

One prominent application of undecimal in computing is the International Standard Book Number (ISBN-10) system, introduced in and used until for identifying . The check digit in ISBN-10 employed modulo-11 arithmetic to validate the nine preceding digits, leveraging base 11 to enhance detection. This allowed the check digit to range from 0 to 10, with 10 represented by the symbol 'X', ensuring the entire 10-character code could detect single-digit errors and adjacent transpositions reliably due to 11's primality. The check digit d is calculated as follows: Let the first nine digits be d_1, d_2, \dots, d_9. Compute the weighted sum s = \sum_{k=1}^{9} (11 - k) d_k = 10 d_1 + 9 d_2 + \dots + 2 d_9. Then, d = (11 - (s \mod 11)) \mod 11, where d = 10 is denoted as 'X' and d = 11 (or equivalently 0 after modulo) is 0. This formula ensures the total weighted sum including the check digit is divisible by 11, providing robust verification. For example, for the partial ISBN 0-306-40615, the sum s = 130, $130 \mod 11 = 9, so d = 11 - 9 = 2, yielding 0-306-40615-2. In broader contexts, undecimal's prime base facilitates error detection in checks and coding schemes, as operations a prime like 11 minimize undetected errors compared to composite bases. This property underpins its utility in legacy verification algorithms beyond , where prime moduli ensure changes in digits alter the predictably. By 2007, ISBN-10 was largely replaced by ISBN-13, which uses -10 for with global barcoding standards, though its undecimal-based retains in digital libraries and archival systems as of 2025.

In Science and Technology

Undecimal finds limited application in science and technology, overshadowed by the widespread adoption of decimal systems rooted in human anatomy and historical conventions. Despite its rarity, base-11 encoding has emerged in niche areas of data representation, particularly for handling complex biological sequences where prime bases like 11 enhance error detection in finite fields. In biotechnology, undecimal serves as an intermediate encoding step in error-correcting codes designed for labeled DNA sequences, enabling robust correction of substitutions, insertions, and deletions during genomic labeling and visualization. For instance, a 2025 construction uses a Hamming code over the finite field GF(11) to encode DNA labels from a 10-symbol alphabet into base-11 representations, which are then converted to base-4 for synthesis, achieving single-error correction with redundancy less than ⌈log₂(n+1)⌉ + 6 bits for sequence length n. This approach supports applications in microbiology and genomics, where accurate sequence recovery is critical despite noisy labeling processes, though it remains experimental without broad adoption. As a prime base, undecimal's properties contribute to error resistance in such finite-field constructions by avoiding non-trivial divisors that could complicate code design. In , the numeral 11 appears prominently in , a unifying framework for superstring theories formulated in 11-dimensional , but this refers to dimensionality rather than a literal base-11 . No direct undecimal notation is employed in these models, highlighting the coincidental numerical overlap rather than practical encoding use. As of 2025, undecimal's role in science and technology remains marginal, underscoring its potential in specialized encoding but affirming its limited adoption amid decimal dominance.

Cultural and Illustrative Aspects

In Popular Fiction

In popular fiction, the undecimal numeral system frequently serves as a marker of extraterrestrial or advanced cognition, underscoring its unfamiliarity to human decimal conventions and evoking themes of cosmic mystery. A prominent example appears in Carl Sagan's 1985 science fiction novel Contact, where astronomer Ellie Arroway deciphers an alien signal that embeds a deliberate message within the base-11 representation of the constant π; after approximately 10^{20} digits, a sequence of 0s and 1s aligns to form a perfect circle, interpreted as evidence of an intelligent creator altering a universal mathematical truth. This revelation, occurring deep in the irrational expansion of π, symbolizes the intersection of science, faith, and interstellar communication, positioning undecimal as a tool for conveying profound, non-human intelligence. The 1990s television series similarly incorporates undecimal into its portrayal of alien cultures, with the Minbari race using base-11 arithmetic derived from counting on ten fingers plus their head, as revealed by aide Lennier during a conversation in the episode "" (season 1, episode 21, aired 1994). This detail highlights the Minbari's philosophical and mathematical divergence from humanity, integrating undecimal into broader world-building to emphasize cultural otherness amid interstellar diplomacy. Such representations typically emphasize undecimal's symbolic role in signifying otherworldliness or intellectual superiority, often without accurate computational details, thereby sparking reader and viewer curiosity about numeral systems.

Mathematical Examples

Undecimal operates on the principle of with base 11, where carries in and borrowing in occur when values reach or exceed 11, unlike the base-10 of 10. This adjustment leads to unique patterns, such as results that may require multiple carries within a single operation, and divisibility rules that differ from norms—for instance, there is no simple "even" rule analogous to checking the last in base 10, as divisibility by 2 depends on the of the last but without the familiar convenience for multiples of 5 or 11.

Addition in Undecimal

Addition in base 11 proceeds digit by digit from right to left, summing corresponding place values and carrying 1 to the next column whenever the total equals or exceeds 11 (denoted as A in digit symbols, where A represents 10). For example, adding $5_{11} + 6_{11} yields $10_{11}, since $5 + 6 = 11_{10} = 1 \times 11 + 0 = 10_{11}. A more involved example is $8_{11} + 9_{11} = 16_{11}, as $8 + 9 = 17_{10} = 1 \times 11 + 6 = 16_{11}. To illustrate the full range of single-digit additions up to 9, the following table shows sums in undecimal (using A for 10):
+0123456789
00123456789
1123456789A
223456789A10
33456789A1011
4456789A101112
556789A10111213
66789A1011121314
7789A101112131415
889A10111213141516
99A1011121314151617
Note that results like 10 represent $1 \times 11 + 0 = 11_{10}, and carries would apply in multi-digit sums.

Multiplication in Undecimal

Multiplication tables in base 11 extend the decimal pattern but account for products up to A \times A = 100_{11} (since $10 \times 10 = 100_{10} = 1 \times 11^2 + 0 \times 11 + 0). For single-digit multiplications up to 9 × 9, the table below provides results in undecimal (e.g., $5_{11} \times 6_{11} = 28_{11}, as $5 \times 6 = 30_{10} = 2 \times 11 + 8 = 28_{11}). For $9_{11} \times 9_{11} = 74_{11}, since $9 \times 9 = 81_{10} = 7 \times 11 + 4 = 74_{11}:
×0123456789
00000000000
10123456789
202468A11131517
303691114171A2225
404811151922262A33
505A14192328323741
606111722283339444A
707131A263239455158
80815222A3744515966
909172533414A586674

Conversions Involving Undecimal

Conversions between bases highlight undecimal's structure. To convert the decimal number 16 to undecimal, divide by 11: 16 ÷ 11 = 1 5, so $15_{11} (1 × 11 + 5 = 16_{10}). Conversely, the 10000_2 = 16_{10} is also $15_{11}. For a larger example, 121 converts to $100_{11}, as shown in the powers section. These operations use repeated by the target for to-undecimal and / for from-undecimal.

Division in Undecimal

Division in undecimal employs long division, using the base-11 multiplication table to find quotients digit by digit, with remainders less than 11. Focusing on integer division, consider $22_{11} \div 2_{11}. First, $22_{11} = 2 \times 11 + 2 = 24_{10}, $2_{11} = 2_{10}, so quotient $11_{11} (12_{10}), since $2_{11} \times 11_{11} = 22_{11}, with no remainder. In steps: 2 into 2 goes 1 time (1 × 2 = 2), subtract 0, bring down 2, 2 into 2 goes 1 time, total quotient $11_{11}. For a non-trivial case, dividing $100_{11} (121_{10}) by $5_{11} (5_{10}) yields quotient $22_{11} (24_{10}), since $5_{11} \times 22_{11} = A0_{11} (120_{10}), remainder $1_{11} (1_{10}). The process involves testing multiples using the multiplication table.

References

  1. [1]
    Undecimal Definition (Illustrated Mathematics Dictionary) - Math is Fun
    A way of writing numbers using 11 digits. Uses the normal decimal digits 0 to 9 with the letter "A" used for the 11th digit: 0,1,2,3,4,5,6,7,8,9,A.Missing: numeral | Show results with:numeral
  2. [2]
    Intro to number bases & How to do binary numbers - Purplemath
    11 number base is called the "undecimal" base; base-12 is called "dozenal" (as in, "it has a dozen digits"). The base-8 system is called "octal"; the base ...
  3. [3]
    [PDF] THE JOURN AL OF THE POLYNESIAN SOCIETY - PhilPapers
    ABSTRACT: The idea the New Zealand Māori once counted by elevens has been viewed as a cultural misunderstanding originating with a mid-nineteenth-century.
  4. [4]
    (PDF) Rarities in numeral systems - Academia.edu
    ... base-11 exist, both of which appear to be mis- taken. Pañgwa (Bantu/Atlantic-Congo, Tanzania) is presented with a base- 11 vocabulary (Johnston 1922a:477) ...
  5. [5]
    Joseph-Louis Lagrange | Research Starters - EBSCO
    To suppress the reformers, Lagrange argued ironically for the advantages of a system with base 11, or any prime, since then all fractions would have the same ...
  6. [6]
    [PDF] The Edit–Compile–Run Cycle - Northwestern Computer Science
    Numeral systems base counting. 2 (binary). 0, 1, 10, 11, 100, 101, 110 ... 11 (undecimal). 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, A, 10, 11, 12, 13, 14, 15, 16.
  7. [7]
    Positional Systems and Bases | Mathematics for the Liberal Arts
    Practically any positive integer greater than or equal to 2 can be used as a base for a number system. Such systems can work just like the decimal system except ...
  8. [8]
    Converting from Decimal to base B
    The following algorithm converts number from base 10 representation to base B respresentation. i := 0; number := number to be converted while number > 0 do ...
  9. [9]
    11.5 From Decimal to Base b
    From decimal to base with Algorithm 11.27. We convert the base 10 number 23 to base 3 using Algorithm 11.27. The base 3 expansion of 23 is . 23 = 2 ⋅ 3 2 + 1 ⋅ ...
  10. [10]
    Base Conversion Tool - Math is Fun
    Base Conversion Tool ; Undecimal (Base 11) · Undecimal: · 10, 11 ; Duodecimal (Base 12) · 13 · Duodecimal: · B, 10 ; Hexadecimal (Base 16) · 13, 14, 15, 16, 17 ...Missing: formula | Show results with:formula
  11. [11]
    [PDF] L2/13-054 - Unicode
    Mar 30, 2013 · 1.3 The digit forms propagated by Isaac Pitman in the 1860s​​ 8) as follows: … The signs “↊,↋” represent the numbers ten and eleven, and “10” ...
  12. [12]
    [PDF] Manual Dozenal System
    Numeration Throughout is Dozenal (Base Twelve). 0 1 2 3 4 5 6 7 8 9 X E 10 where X is ten, E is eleven, and 10 is a dozen. Page 2. Dozenal numeration is a ...
  13. [13]
    Non-power positional number representation systems, bijective ...
    It is perfectly possible to have a positional number system without a zero (see the Methods section for an introduction to number representation systems). This ...
  14. [14]
    [PDF] The Universal History Of Numbers
    ... base 11. This would be much more useful than base 10 or 12, since under base ... French Revolution offered “to all ages and to all peoples, for their.
  15. [15]
    Joseph-Louis Lagrange - Biography - University of St Andrews
    Joseph-Louis Lagrange was an Italian-born French mathematician who excelled in all fields of analysis and number theory and analytical and celestial mechanics.
  16. [16]
    (PDF) The curious idea that Māori once counted by elevens, and the ...
    Aug 6, 2025 · The affair is traced to a pair of scientific explorers, René-Primevère Lesson and Jules Poret de Blosseville, as reconstructed through their ...Missing: Victor | Show results with:Victor
  17. [17]
    A dictionary of the New Zealand language - Internet Archive
    Mar 10, 2008 · A dictionary of the New Zealand language : to which is added a selection of colloquial sentences. by: Williams, William, 1800-1878.Missing: tekau tahi
  18. [18]
    32. Duodecimal Base of Numeration. - jstor
    To make the priority of the decimal system probable it should be shown that the numbers for eleven and twelve imply not only the idea of ten, but the base of ...
  19. [19]
    None
    Below is a merged summary of the Pangwa numerals based on the provided segments from Sir Harry H. Johnston’s *A Comparative Study of the Bantu and Semi-Bantu Languages*, Volume II, focusing on page 477 or nearby pages. The information is synthesized into a concise narrative with a table for detailed numeral data where applicable. Since the system has a "no thinking token" limit, I’ll prioritize factual content from the summaries without additional inference or speculation.
  20. [20]
    https://www.ece.unb.ca/tervo/ee4253/isbn.shtml
  21. [21]
    [PDF] Tense and Aspect in Pangwa
    Dec 7, 2021 · The total number of Pangwa speakers in Tanzania is estimated to be 95,000 (SIL 2003: 2). According to a sociolinguistic study conducted by SIL.Missing: numerals | Show results with:numerals
  22. [22]
    Secrets of the ISBN - An Error Detection Method
    With no alternate method of obtaining a result which is an exact multiple of 11, the ISBN is guaranteed to detect all single-digit errors and all swapped-digit ...
  23. [23]
    ISBN -- from Wolfram MathWorld
    The last digit is a check digit which may be in the range 0-9 or X (where X is the Roman numeral for 10) for an ISBN-10, or 0-9 for an ISBN-13. For ISBN-10, the ...
  24. [24]
    Barcoding Guidelines for the US Book Industry
    Conversions and Calculations. It is sometimes necessary to convert 10-digit ISBNs to Bookland EANs, to retrieve a 10-digit ISBN from a Bookland EAN beginning ...
  25. [25]
    Why don't we use base 6 or 11? - Mathematics Stack Exchange
    Aug 6, 2013 · Why don't we use base 6 or 11? · 1. Historical considerations aside, every positional number system needs a digit (corresponding to) 0. · 36 is ...Missing: undecimal | Show results with:undecimal
  26. [26]
    Inline SAW RFID tag using time position and phase encoding
    Aug 6, 2025 · Surface acoustic wave (SAW) radio-frequency identification (RFID) tags are encoded according to partial reflections of an interrogation ...Missing: base- | Show results with:base-
  27. [27]
    Patterns in pi in "Contact" - Mathematics Stack Exchange
    Jan 14, 2015 · The base 11 representation of π contains a sequence of ones and zeros that, when properly aligned on a page, produce a circular pattern.Missing: fiction media
  28. [28]
    Carl Sagan's Conjecture of a Message in π
    In his novel Contact, the astrophysicist Carl Sagan hypothesized an alien message to be buried somewhere deep inside the numerical representation of the ...
  29. [29]
    Guide Page: "The Quality of Mercy" - Midwinter
    May 27, 2024 · Minbari use base 11, not base 10, so twelve would be eleventy-first year, and so on. Minbari base eleven includes fingers and head, from ...Missing: transcript | Show results with:transcript
  30. [30]
    5.3: Calculating in Other Bases
    ### Summary of Arithmetic Operations in Other Bases
  31. [31]
    Number Bases - Math is Fun
    And so on! Undecimal (Base 11). Undecimal (Base 11) needs one more digit than Decimal, so "A" is used, like this: Decimal: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 ...
  32. [32]
    Division in base eleven - Math Central - University of Regina
    Question from Zoe, a student: How do you divide numbers that are in base 11? For example;. 9A7A6A divided by A. Please help me! :) I need the answer quickly ...