Scientists have tried contacting extraterrestrials with a number of bespoke linguistic systems. But we might be better off using our own languages.
This custom symbolic system begins by introducing ET to numerals, and then progresses to more complex topics like human biology and the planets in our solar system. An earlier version of the language was first sent into space in 1999 and again in 2003 as part of the Cosmic Call messages—a crowd-sourced interstellar messaging project that marked the first serious attempt at interstellar communication since Carl Sagan and Frank Drake sent the Arecibo message into space 25 years earlier.
All of these formal messaging attempts have taken basically the same approach: Teach numerals and basic arithmetic first. But as some recent insights in neurolinguistics suggest, it might not be the best way to greet our alien neighbors.
The world’s first interstellar communication system, the lingua cosmica, or Lincos, set the tone for all subsequent attempts by placing basic math at its core. Designed by the Dutch mathematician Hans Freudenthal in 1960, Lincos inspired several other mathematicians and scientists to try their hand at designing extraterrestrial languages. Each system is ultimately an attempt at solving a remarkably complex problem: How do you communicate with an intelligent entity you know nothing about?
The question gets at the nature of intelligence itself. Humans are the only species on Earth endowed with advanced mathematical ability and a fully fledged faculty of language, but are these hallmarks of intelligence or human idiosyncrasies? Is there an aspect of intelligence that is truly universal?
Scientists and mathematicians have grappled with these questions for centuries. As the Nobel laureate Eugene Wigner once observed, mathematics is “unreasonably effective” at describing the natural universe, which has led a significant contingent of mathematicians to conclude that math is baked into the fabric of reality. From this perspective, mathematics isn’t something produced by the human mind so much as something the human mind discovers.
Most interstellar communication systems were designed around this conclusion. The goal isn’t to teach ETs about addition and subtraction—presumably they know as much if they can build a telescope to receive the message. Instead, these systems teach ETs about the way we code numbers as symbols. Then they can build up to more complex ideas.
It’s an elegant solution to a difficult problem, but Lincos still rests on the assumption that an ET is “human-like in its mental state,” as Freudenthal once conceded. But if ET does in fact think like a human, does that alien also have some kind of human-like language?
That was where Marvin Minsky and John McCarthy, two of the progenitors of artificial intelligence, landed after they became interested in interstellar communication. Both Minsky and McCarthy had a deep interest in the search for extraterrestrial intelligence, which they realized had a lot in common with their own search for artificial intelligence. As Minsky argued on several occasions, ET is likely to have language because language is an ideal solution to the fundamental problems faced by any intelligent species—namely constraints on time, energy, and resources.
A deeper question is whether ET’s language will be similar to our own. In other words, whether it will also obey the universal grammar, the hierarchical, recursive structure that linguist Noam Chomsky has argued is the deep structure common to all human languages. Although languages tend to be analogized as a form of software running on the hardware of our brain, recent work in neurolinguistics suggests that language—and the universal grammar—is actually an expression of the hardware itself.