Reverse-engineering the universal translator
Cinema critics keep raving about Arrival, a sci-fi drama by Denis Villeneuve focusing on one linguist’s attempts to decipher an alien language. Star Trek recently celebrated its 50th anniversary. As a language geek and a sci-fi fan, I felt it only logical to look into the feasibility of the universal translator, the device used by the crew of the Starship Enterprise.
No, this is not yet another post about machine translation. This technology is already a reality with a variety of approaches and new promising developments. While not yet at the level of a human translation expert, machine translation is already usable in multiple scenarios. (Translation of known languages is, of course, also a part of the Star Trek universal translator, and on some occasions Star Trek linguists have to tweak the linguistic internals manually.)
This article will focus on the device’s decoding module for unknown languages, or decipherment.
Decipherment in real life
No matter how elaborate, all decipherment techniques have the same core: pairing an unknown language with known bits of knowledge. The classic Rosetta Stone story is the most famous example: A tablet with inscriptions of Ancient Egyptian hieroglyphs, Ancient Greek and another Egyptian script (Demotic) was used as a starting point to understand a long-dead language.
Today, statistical machine translation engines are generated in a similar fashion, using parallel texts as “virtual Rosetta Stones.” If, however, a parallel text is not available, the decipherment relies on closely related languages or whatever cues can be applied.
Perhaps the most dramatic story of decipherment is that of the Maya script, which involved two opposing points of view amplified by Cold War tensions. More recently, Regina Barzilay from MIT decoded a long-dead language using machine learning assuming similarity with a known language.
But what happens when there is no Rosetta Stone or similar language? In face-to-face interaction, like the scenario depicted in Arrival, gestures, physical objects and facial expressions are used to build the vocabulary. These methods were used by the seafarers exploring the New World and are occasionally employed today by anthropologists and linguists, like Daniel Everett who spent decades working with the Pirahã people in the Amazon.
Life imitates fiction: lingua universalis
But what if the face-to-face interaction is not possible?
For decades, SETI researchers have been scanning the skies for signs of extraterrestrial intelligence. Some of them specifically focus on the questions, “what happens if we do get a signal?” and “how do we know if this is a signal and not just noise?”
The two most notable SETI people working on these issues are Laurance Doyle and John Elliott. Doyle’s work focuses on the application of Claude Shannon’s information theory to determine whether a communication system is similar to human communication in its complexity. Doyle, together with the famous animal behavior and communication researcher Brenda McCowan, analyzed various animal communication data, comparing its information theory characteristics to those of human languages.
No matter how elaborate, all decipherment techniques have the same core: pairing an unknown language with known bits of knowledge.
John Elliott’s work specifically focuses on unknown communication systems; the publication topics range from detecting whether the transmission is linguistic to assessing the structure of the language, and, lastly, on building what he calls a “post-detection decipherment matrix.” In Elliott’s own words, this matrix would use a “corpus that represents the entire ‘Human Chorus’ ” applying unsupervised learning tools, and, in his later works, include other communication systems (e.g. animal communication). Elliott’s hypothetical system relies on an ontology of concepts with a “universal semantic metalanguage.” (Just like Swadesh lists compile a set of shared basic concepts.)
Interestingly, there are certain similarities between the fictional universal translator and the ways real-life scientists attack the problem. According to Captain Kirk’s explanation, “certain universal ideas and concepts” were “common to all intelligent life,” and the translator compares the frequencies of “brainwave patterns,” selects those ideas it recognized and provides the necessary grammar.
Assuming that a variety of hypothetical neural centers may produce recognizable activity patterns (brainwaves or not), and that communication produces a stimulus that activates specific areas in the neural center, the approach may have merit — provided the hardware sensitive enough to detect these fluctuations will be available. The frequency analysis is also in line with Zipf’s law, which is mentioned throughout the work of Elliott and Doyle.
Other Star Trek series keep mentioning a vaguely described translation matrix, which is used to facilitate translation. Artistic license and techno-babble aside, the word “matrix” and the sheer number of translation pair combinations correspond to a real-world interlingua model, which employs an abstract, language-independent representation of knowledge.
There are a couple of occasions in Star Trek where a certain linguacode, used as a last-resort tool when the universal translator doesn’t work, is mentioned. The linguacode may also have a real-world equivalent called lincos. Lincos, together with its derivatives, is a constructed language designed to communicate with other species using universal mathematical concepts.
View from the engine room
As someone who spent more than a decade working on a language-neutral semantic engine, I got very excited when I realized that the system and the ontology described by Elliott as a prerequisite to the semantic analysis is very close to what I constructed. Bundling all of the languages into a “human chorus” may steer the system toward a “one-size-fits-all” result, which is too far from the target communication system.
It doesn’t have to be this way; with a system capable of mapping both syntactic structures and semantics (not just a limited set of entities), it is possible to build a “corpus of scenarios” that will allow for building more accurate ordered statistical models relying on the universality of interaction scenarios.
- Most messages meant to be a part of a dialogue, in most languages, start with a greeting.
- Most technical documents contain numbers.
- All demands contain a request, and, often, a threat.
- News accounts refer to an event.
- Most long documents are divided into chapters and so have either numbers or chapter names between the chapters.
- Reference articles describe an entity.
The reasons for that have nothing to do with a structure of a particular language, and generally stem from the venerable principle of least effort or necessities for efficient communication in groups.
Using a system that runs on semantics will allow building a corpus without the dependency on surface representation and instead records word senses, and creates a purely semantic and a truly universal corpus. Having syntactic structures semantically grouped opens up even more possibilities.
Instead of a Rosetta Stone, this system could serve as a high-tech “Rosetta Rubik’s Cube,” with an immense number of combinations being run until the best matching combination is found.
Is it possible to test the hypothetical “universal translator” software on something more accessible than a hypothetical communication from extraterrestrial intelligence? Many researchers believe so. While it has not been proven that cetacean communication has all the characteristics of human language, there is evidence that strongly suggests it could.
Dolphins, for example, use so-called individual signature whistles, which appear to be equivalent to human names. Among other things, the signature whistles are used to locate individuals, and therefore, meet one of the requirements for a communication system to be considered a language: displacement. In the course of Louis Herman’s experiments, dolphins managed to learn an adapted version of American Sign Language to understand abstract concepts like “right” or “left. Lastly, the complex social life of dolphins requires coordination of activities that can be only achieved by efficient and equally complex communication.
In addition to the often-cited cetaceans, there is evidence of other species having complex communication systems. A series of experiments has shown that ant communication may be infinitely productive (that is, have infinite amount of combinations like human language does) and that it may efficiently “compress” content (e.g. instead of saying “turn left, left, left, left” say “turn left four times”).
Both Doyle and Elliott studied cetacean communication with various tools provided by information theory. Elliott calculated entropy for human language, bird song, dolphin communication and non-linguistic sources like white noise or music.
Communication systems share a “symmetric A-like amplitude” shape: more symmetric for humans and dolphins, less symmetric for birds. Doyle conducted similar measurements with humpback whale vocalizations and arrived at similar conclusions.
This is why several animal communication initiatives are coordinated with the SETI initiatives. A truly universal decipherment framework would be incomplete without the ability to ingest and learn a complex animal communication system.
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