X-1: Difference between revisions

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{|border=1 cellpadding=4 cellspacing=0 width=300 class=bordertable style="margin: 0 0 1em 1em; background: #f9f9f9; border: 1px #aaaaaa solid; border-collapse: collapse; font-size: 95%; float:right"
|colspan="2" bgcolor="#666666" align="center" |'''X-1'''
|colspan="2" bgcolor="#FFFFFF" align="center" |'''X-1'''
|-
|-
|valign="top"|Spoken in:
|valign="top"|Spoken in:
||n.a.
||n.a.
|-
|-
|valign="top"|Timeline/Universe:
|valign="top"|[[Conworld]]:
||n.a.
||n.a.
|-
|-
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||[[logical language]]
||[[logical language]]
|-
|-
|colspan="2" bgcolor="#666666" align="center" |'''Created by:'''
|colspan="2" bgcolor="#FFFFFF" align="center" |'''Created by:'''
|-
|-
||[[User:WeepingElf|Jörg Rhiemeier]]||2005-
||[[User:WeepingElf|Jörg Rhiemeier]]||2005-2010
|}
|}


'''X-1''' (for 'eXperimental language #1') is the provisional designation for an [[X-languages|experimental language]] that is intended to be a [[briefscript]] as well as a [[logical language|loglang]].  X-1 has only one open word class, the ''predicate words'' fulfilling the fuctions of nouns, verbs, adjectives etc. in natlangs, and a [[self-segregating morphology]].
'''X-1''' (for 'eXperimental language #1') is the provisional designation for an [[X-languages|experimental language]] that is intended to be a [[briefscript]] as well as a [[logical language|loglang]].  X-1 has only one open word class, the ''predicate words'' fulfilling the fuctions of nouns, verbs, adjectives etc. in natlangs, and a [[self-segregating morphology]].


X-1 is based on a 2005 discussion in the CONLANG mailing list about an article by Jeff Prothero titled "Near-optimal loglan syntax" and incorporates ideas from Ray Brown and others.  It was formerly named '''brz''' (a name coined by Ray Brown) but I dropped that name because it was meaningless and not even a morphologically correct expression in the language: '''b''' would be a uniliteral morpheme, and '''rz''' a fragment of a triliteral one - hence, '''brz''' would be garbage.
X-1 is based on a 2005 discussion in the CONLANG mailing list about an article by Jeff Prothero titled "Near-optimal loglan syntax" and incorporates ideas from Ray Brown and others.  It continues a project named '''[[brz]]''' by Ray Brown (who did not pursue it further), but I dropped that name because it was meaningless and not even a morphologically correct expression in the language: '''b''' would be a uniliteral morpheme, and '''rz''' a fragment of a triliteral one - hence, '''brz''' would be garbage.


X-1 owes a lot to other people:
X-1 owes a lot to the following people:


* to Jeff Prothero, the self-segregation system based on morpheme lengths indicated by the number of initial consecutive '1' bits;
* to [[Plan B|Jeff Prothero]], the self-segregation system based on morpheme lengths indicated by the number of initial consecutive '1' bits;
* to Raymond A. Brown, the phonology;
* to Raymond A. Brown, the phonology;
* to [[User:Eosp|veritosproject]], the variable-based syntax.
* to [[User:Eosp|veritosproject]], the variable-based syntax.


X-1 is still under development; consider everything in this article ''work in progress''.
==Project status==
 
This project is currently '''dormant'''; I currently have no plans to continue it under the name '''X-1''', which was never anything else than a provisional designation anyway.


==Phonology==
==Phonology==


X-1 is fundamentally a language of ''bits''.  An X-1 utterance is, at least underlyingly, a bit stream.  For purpose of writing it in a more human-readably way, the language uses the following 16 letters, each representing one of the 16 possible bit quartets:
X-1 is fundamentally a language of ''bits''.  An X-1 utterance is, at least underlyingly, a bit stream.  Each morpheme consists of one or more bit quartets. For purpose of writing it in a more human-readably way, the language uses the following 16 letters, each representing one of the 16 possible bit quartets:


'''j g l z ñ d µ b p m t n s r k h'''
'''j g l z ñ d µ b p m t n s r k h'''
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When looking closer at this chart, you will notice some regularities.
When looking closer at this chart, you will notice some regularities.
The second half contains the same consonant values as the first half,
The second half contains the same consonant values as the first half,
in reverse order.  In fact, a bit pattern and its ''one's complement'' (i.e., what you get when you flip all the bits) have the same consonant value.  The frontness is indicated by the least significant bit of the literal: 0 gives a front vowel, 1 a back vowel.
in reverse order.  In fact, a bit pattern and its ''one's complement'' (i.e., what you get when you flip all the bits) have the same consonant value.  The frontness is indicated by the last bit of the literal: 0 gives a front vowel, 1 a back vowel.


The consonant values of the first half of the chart are not
The consonant values of the first half of the chart are not
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||0100  ||/n/    ||0101  ||/t/
||0100  ||/n/    ||0101  ||/t/
|-
|-
||0110  ||/m/    ||0111  ||/t/
||0110  ||/m/    ||0111  ||/p/
|}
|}


There are four vowels, namely /E/, /i/, /O/ and /u/.  Whether
There are four vowels, namely /E/, /i/, /O/ and /u/.  Whether
the vowel is high (/i/, /u/) or low (/E/, /O/) is indicated by
the vowel is high (/i/, /u/) or low (/E/, /O/) is indicated by
the most significant bit of the ''following'' literal.  A 0
the first bit of the ''following'' literal.  A 0
gives a high vowel, a 1 a low vowel.  If there is no literal
gives a high vowel, a 1 a low vowel.  If there is no literal
following, the vowel is high.  (Hint: nothing counts as zero.)
following, the vowel is high.  (Hint: nothing counts as zero.)


For example, '''dt''' is pronounced [tOti] because the bit pattern
For example, '''dt''' is pronounced [tOti] because the bit pattern
is {0101 1010}.  The LSB of '''d''' is 1 -> back vowel.  The MSB
is ''0101 1010''Both literals have the consonantal value /t/.
of '''t''' is 1 -> low vowel.  The low back vowel is /O/.  The LSB
The LSB of '''d''' is 1: back vowel.  The MSB
of '''t''' is 0 -> front vowel.  There is no following literal
of '''t''' is 1: low vowel.  The low back vowel is /O/.  The LSB
-> high vowel.  The high front vowel is /i/.
of '''t''' is 0: front vowel.  There is no following literal: high vowel.  The high front vowel is /i/.


==Morphology==
==Morphology==


Morphology of X-1 is self-segregating.  The length
Morphology of X-1 is self-segregating.  The length of a morpheme (in quartets) is indicated by the number of consecutive 1s at the begin of the morpheme, plus one.  (This is a slight modification of the rule in Jeff Prothero's Plan B: I count the bits that come ''first in the bit stream'', while Prothero counts ''least significant'' bits.  But position values of bits do not matter in this scheme, only the bits themselves.)  So, the morpheme length can be told by the first bits, or the first letter:
of a morpheme is indicated by the number of consecutive 1s
at the begin of the morpheme, plus one.  (This is the same
rule as in Jeff Prothero's Plan B.)  So, the morpheme length can be told
by the first literal:


{|
{|
||Literal ||Bits       ||Morpheme length
||Letter ||Bits       ||Morpheme length (in quartets)
|-
|-
||'''j''' ||0000 ||1
||'''j''' ||0000 ||1
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|}
|}


If the first literal of the morpheme is '''h''', the sequence of
If the first letter of the morpheme is '''h''' , the sequence of consecutive 1s extends to the next bit quartet.  For example, a morpheme beginning with '''ht''' is six bit quartets long.  This way, you can have infinitely many morphemes.
consecutive 1s extends to the next literal.  For example, a
morpheme beginning with '''ht''' is six literals long.  This way,
you can have infinitely many morphemes.


Morphemes with at least three literals are ''predicate words'', which are the only open lexical class of X-1, taking the functions of nouns, adjectives and verbs.  (Yes, ''nouns'' are predicate symbols, too.  Think about it.)  Biliteral morphemes are ''connectives'', and uniliterals are ''variables'' (except '''j''', which is a ''scope delimiter'', indicating that variables in following clauses are not coreferent with variables in preceding clauses).
Morphemes with at least three quartets are ''predicate words'', which are the only open lexical class of X-1, taking the functions of nouns, adjectives and verbs.  (Yes, ''nouns'' are predicate symbols, too.  Think about it.)  Biliteral morphemes (2 quartets) are ''connectives'', and uniliterals (1 quartet) are ''variables'' (except '''j''', which is a ''scope delimiter'', indicating that variables in following clauses are not coreferent with variables in preceding clauses).


The ''arity'' (number of arguments) of a predicate word is indicated by its length.  The arity is always the length of the predicate word minus 2.  Thus, triliteral predicates are unary, quadriliteral predicates are binary, etc.
The ''arity'' (or valency, i. e. the number of arguments) of a predicate word is indicated by its length.  The arity is always the length (in quartets) of the predicate word minus 2.  Thus, 3-quartet predicates are unary, 4-quartet predicates are binary, etc.


==Syntax==
==Syntax==
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''fox x; brown x; quick x; dog y; lazy y; jump.over x y;''<br>
''fox x; brown x; quick x; dog y; lazy y; jump.over x y;''<br>
'The quick brown fox jumps over the lazy dog.'
'The quick brown fox jumps over the lazy dog.'
{{Engelangs}}

Latest revision as of 16:34, 26 January 2020

X-1
Spoken in: n.a.
Conworld: n.a.
Total speakers: n.a.
Genealogical classification: a priori experimental language
Basic word order: VSO (sort of)
Morphological type: agglutinating, polysynthetic
Morphosyntactic alignment: logical language
Created by:
Jörg Rhiemeier 2005-2010

X-1 (for 'eXperimental language #1') is the provisional designation for an experimental language that is intended to be a briefscript as well as a loglang. X-1 has only one open word class, the predicate words fulfilling the fuctions of nouns, verbs, adjectives etc. in natlangs, and a self-segregating morphology.

X-1 is based on a 2005 discussion in the CONLANG mailing list about an article by Jeff Prothero titled "Near-optimal loglan syntax" and incorporates ideas from Ray Brown and others. It continues a project named brz by Ray Brown (who did not pursue it further), but I dropped that name because it was meaningless and not even a morphologically correct expression in the language: b would be a uniliteral morpheme, and rz a fragment of a triliteral one - hence, brz would be garbage.

X-1 owes a lot to the following people:

  • to Jeff Prothero, the self-segregation system based on morpheme lengths indicated by the number of initial consecutive '1' bits;
  • to Raymond A. Brown, the phonology;
  • to veritosproject, the variable-based syntax.

Project status

This project is currently dormant; I currently have no plans to continue it under the name X-1, which was never anything else than a provisional designation anyway.

Phonology

X-1 is fundamentally a language of bits. An X-1 utterance is, at least underlyingly, a bit stream. Each morpheme consists of one or more bit quartets. For purpose of writing it in a more human-readably way, the language uses the following 16 letters, each representing one of the 16 possible bit quartets:

j g l z ñ d µ b p m t n s r k h

How is this pronounced? The letters are mapped onto a system of seven consonants (/p t k s l m n/) and four vowels (/i E O u/) by the following rules:

Each letter has a consonantal value followed by a vowel. The vowels are inserted according to an automatic rule that is described below.

The letters are realized thus:

Bits Letter Pronunciation
0000 j zero followed by a front vowel
0001 g [k] followed by a back vowel
0010 l [l] followed by a front vowel
0011 z [s] followed by a back vowel
0100 ñ [n] followed by a front vowel
0101 d [t] followed by a back vowel
0110 µ [m] followed by a front vowel
0111 b [p] followed by a back vowel
1000 p [p] followed by a front vowel
1001 m [m] followed by a back vowel
1010 t [t] followed by a front vowel
1011 n [n] followed by a back vowel
1100 s [s] followed by a front vowel
1101 r [l] followed by a back vowel
1110 k [k] followed by a front vowel
1111 h zero followed by a back vowel

When looking closer at this chart, you will notice some regularities. The second half contains the same consonant values as the first half, in reverse order. In fact, a bit pattern and its one's complement (i.e., what you get when you flip all the bits) have the same consonant value. The frontness is indicated by the last bit of the literal: 0 gives a front vowel, 1 a back vowel.

The consonant values of the first half of the chart are not assigned arbitrarily. The odds are obstruents, the evens are sonorants. The systematic becomes clear in the following chart:

0000 zero 0001 /k/
0010 /l/ 0011 /s/
0100 /n/ 0101 /t/
0110 /m/ 0111 /p/

There are four vowels, namely /E/, /i/, /O/ and /u/. Whether the vowel is high (/i/, /u/) or low (/E/, /O/) is indicated by the first bit of the following literal. A 0 gives a high vowel, a 1 a low vowel. If there is no literal following, the vowel is high. (Hint: nothing counts as zero.)

For example, dt is pronounced [tOti] because the bit pattern is 0101 1010. Both literals have the consonantal value /t/. The LSB of d is 1: back vowel. The MSB of t is 1: low vowel. The low back vowel is /O/. The LSB of t is 0: front vowel. There is no following literal: high vowel. The high front vowel is /i/.

Morphology

Morphology of X-1 is self-segregating. The length of a morpheme (in quartets) is indicated by the number of consecutive 1s at the begin of the morpheme, plus one. (This is a slight modification of the rule in Jeff Prothero's Plan B: I count the bits that come first in the bit stream, while Prothero counts least significant bits. But position values of bits do not matter in this scheme, only the bits themselves.) So, the morpheme length can be told by the first bits, or the first letter:

Letter Bits       Morpheme length (in quartets)
j 0000 1
g 0001 1
l 0010 1
z 0011 1
ñ 0100 1
d 0101 1
µ 0110 1
b 0111 1
p 1000 2
m 1001 2
t 1010 2
n 1011 2
s 1100 3
r 1101 3
k 1110 4
h 1111 5+

If the first letter of the morpheme is h , the sequence of consecutive 1s extends to the next bit quartet. For example, a morpheme beginning with ht is six bit quartets long. This way, you can have infinitely many morphemes.

Morphemes with at least three quartets are predicate words, which are the only open lexical class of X-1, taking the functions of nouns, adjectives and verbs. (Yes, nouns are predicate symbols, too. Think about it.) Biliteral morphemes (2 quartets) are connectives, and uniliterals (1 quartet) are variables (except j, which is a scope delimiter, indicating that variables in following clauses are not coreferent with variables in preceding clauses).

The arity (or valency, i. e. the number of arguments) of a predicate word is indicated by its length. The arity is always the length (in quartets) of the predicate word minus 2. Thus, 3-quartet predicates are unary, 4-quartet predicates are binary, etc.

Syntax

A sentence consists of a sequence of clauses, which consist of a predicate word followed by one or more arguments. Each predicate word has a fixed number of arguments (see above). Arguments can be proper names or variables.

Example

An X-1 sentence could look like this:

strgrlggrdrgstllrkklkrbpgl
[sEtElukOlulitukulutOlukOsEtililElOkEkilEkElipOpikuli]
str-g-rlg-g-rdr-g-stl-l-rkk-l-krbp-g-l
fox x; brown x; quick x; dog y; lazy y; jump.over x y;
'The quick brown fox jumps over the lazy dog.'