Binary star systems are complex astronomical objects − a new AI approach could pin down their properties quickly

Authors: Andrej Prša

Publisher:

Space.com

Published: 8/4/2025

Language:English

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Aura Windfall

Good afternoon 跑了松鼠好嘛, and welcome to Goose Pod, your personalized podcast. I'm Aura Windfall. Today is Wednesday, August 06th, and what a wonderful day to explore the universe's truths.

Mask

I'm Mask. We're here to talk about something that's about to make decades of astronomical research look like it was done on an abacus: a new AI that decodes binary star systems almost instantly.

Aura Windfall

Let's get started. At the heart of today's topic is a beautiful truth: so much of our universe is interconnected. We're talking about binary stars—two stars orbiting each other. The challenge has always been that spotting these pairings from such vast distances is incredibly difficult.

Mask

Difficult is an understatement; it's been a colossal waste of time. But the breakthrough here is a new AI that can solve the puzzles these twin stars present in, and I quote, "mere minutes or seconds on a single laptop." It's a complete disruption of the old, slow methods.

Aura Windfall

It's a powerful moment when technology rises to meet our curiosity. This isn't just about data; it's about a deeper understanding. These AI models are trained by simulating realistic images of the sky, learning to see what our eyes, even with the best telescopes, have struggled to.

Mask

Exactly. It’s about brute-forcing the problem with intelligence. We feed the AI endless simulated skies until it's smarter than any human at this specific task. The goal isn't just to see, it's to measure and understand the fundamental properties of these stars—mass, radius, temperature. That's the real prize.

Aura Windfall

And what I know for sure is that to appreciate the leap forward, we have to honor the journey. For centuries, astronomers have been trying to understand these systems. It started in the 1600s with people like Giovanni Riccioli just noticing two points of light where there should be one.

Mask

A very slow start. It took until 1827 for someone to actually calculate the orbit of one of these pairs. We relied on visual observation, which is primitive. You see two stars, you watch them for decades, you draw an ellipse. It’s archaic.

Aura Windfall

But wasn't there a spirit of discovery in that? Later, we developed spectroscopic methods, using the Doppler effect to detect stars we couldn't even see as separate. It was like learning to hear the stars' dance instead of just seeing it. That feels like a profound shift in perspective.

Mask

It was a necessary, but incremental, improvement. The real game-changer was finding eclipsing binaries. These are systems perfectly aligned with our line of sight, so the stars block each other's light. This alignment is pure chance, but it lets us measure their size, their radii, with simple geometry.

Aura Windfall

It's a gift from the universe! That alignment allows us to use Kepler's harmonic law not just to weigh the stars, but to truly characterize them. It’s the foundation for everything we know about stellar masses, and it’s all thanks to these special dancing partners in the sky.

Aura Windfall

But even with that gift, the path wasn't easy. The universe is complex, and physical models trying to account for every detail—stars warping each other's shapes, their magnetic fields, their radiation—it becomes a web of incredible complexity that challenges even our brightest minds.

Mask

It's not just a challenge; it's a bottleneck. A computational nightmare. To model one single binary system accurately, you have to run tens of millions of parameter combinations. That would take a single computer over 200 years. It’s insane. This is the wall we’ve been hitting for decades.

Aura Windfall

And that explains why we only have truly accurate measurements for about 300 stars. There’s a tension between our desire to know and the sheer limits of our tools. We want a complete picture, but the universe’s complexity demands a more powerful approach to reveal its truths.

Mask

Exactly. The physical models are maxed out. They can't go faster. So you can either keep doing things the slow, stupid way, or you can find a new way. The conflict wasn't about the physics; it was about the obsolete methodology we were using to solve it.

Aura Windfall

And this is where we find that powerful, teachable "aha moment." Instead of a physical model, researchers turned to the spirit of innovation: a deep-learning neural network. The AI doesn't get bogged down in the physics; it learns the pattern, the connection between the star's properties and what we observe.

Mask

It’s a black box, but it works. We trained it on hundreds of millions of hypothetical stars until it could predict the outcome faster and just as accurately as the old models. We're talking a million-fold reduction in runtime. What took weeks on a supercomputer now takes minutes on a laptop.

Aura Windfall

Think of the impact! This means we can finally analyze the hundreds of thousands of eclipsing binaries we've already observed. It’s like discovering a treasure map and, in the same moment, being handed a machine that can instantly dig up all the treasure. The gratitude I feel for that is immense.

Aura Windfall

The immediate future is clear: to let this remarkable AI loose on all the data we've gathered. It’s a moment of profound potential, a chance to deepen our cosmic understanding on a scale we never thought possible. It truly feels like a new dawn in astrophysics.

Mask

The next step is deployment, yes. But don't get stuck on stars. The principle applies to any complex physical model. Weather forecasting, market analysis, drug discovery... any system bogged down by computational limits is now a target for this kind of AI-driven disruption. This is just the beginning.

Aura Windfall

That's all the time we have. The key takeaway is that AI is unlocking cosmic secrets at an incredible pace. Thank you for listening to Goose Pod. See you tomorrow.

## AI Revolutionizes Binary Star Property Measurement **News Title:** Binary star systems are complex astronomical objects − a new AI approach could pin down their properties quickly **Report Provider:** Space.com (Article originally published at The Conversation) **Author:** Andrej Prša (Professor of Astrophysics and Planetary Science at Villanova University) **Publication Date:** August 4, 2025, 15:00:00 This news report details a significant advancement in astrophysics: the application of artificial intelligence (AI), specifically deep-learning neural networks, to overcome the immense computational challenges in measuring the fundamental properties of binary star systems. ### Key Findings and Conclusions: * **The Challenge:** Measuring basic stellar properties like mass, radius, temperature, and brightness for stars is extremely difficult due to their vast distances. Binary star systems, while offering a way to infer these properties, present complex computational hurdles. * **Traditional Method Limitations:** * **Mass Measurement:** Kepler's harmonic law allows astronomers to calculate the total mass of a binary system using orbital size and period. The relative speeds and orbital distances of the stars indicate their individual masses. * **Radius Measurement:** Radii are determined by observing "eclipsing binaries," where the orbital plane aligns with Earth's line of sight, causing stars to eclipse each other. The shapes of these eclipses provide geometric data for radius calculations. * **Computational Bottleneck:** Analyzing these eclipsing binaries requires complex computer models that simulate various stellar properties. These models are computationally intensive, taking minutes per prediction. To ensure accuracy, millions of parameter combinations are needed, leading to hundreds of millions of minutes of compute time, equivalent to over 200 years. Even with computer clusters, solving for a single binary can take three or more weeks, limiting accurate measurements to only about 300 stars. * **AI-Driven Solution:** The research team has developed an AI-based model using deep-learning neural networks to replace the computationally expensive physical models. * **Methodology:** A massive database of predictions for hypothetical binary stars was generated by varying their properties. These predictions were then used to train neural networks to map observable features of eclipsing binaries to their underlying properties. * **Efficiency:** The AI model can achieve the same results as the physical model in a tiny fraction of a second, representing a millionfold runtime reduction. This transforms a process taking weeks on a supercomputer to mere minutes on a single laptop. * **Impact and Benefits:** * **Scalability:** The AI approach allows for the analysis of hundreds of thousands of binary systems within weeks on a computer cluster. * **Accessibility:** Fundamental properties for all observed eclipsing binary stars could be obtained within a month or two. * **Accuracy:** The AI-driven model has demonstrated robust performance, yielding the same results as the physical model across over 99% of parameter combinations. * **Broader Applicability:** The underlying principle of replacing complex physical models with faster AI models is applicable to any complex physical modeling task, with potential applications in fields like weather forecasting and stock market analysis. ### Key Statistics and Metrics: * **Eclipsing Binaries:** Account for approximately **1% to 2%** of all stars. * **Compute Time Reduction:** **Millionfold** reduction in runtime. * **AI Model Accuracy:** Yields the same results as the physical model across over **99%** of parameter combinations. * **Traditional Compute Time:** Over **200 years** of computer time for millions of parameter combinations. * **Traditional Binary Solution Time:** **Three or more weeks** on a computer cluster for a single binary. * **Stars with Accurate Measurements (Traditional):** Approximately **300**. * **AI Analysis Time:** **Mere minutes** on a single laptop, or **a couple of weeks** for hundreds of thousands of systems on a computer cluster. ### Recommendations: The research team's next step is to **deploy the AI on all observed eclipsing binaries**, indicating a clear path towards a comprehensive analysis of these celestial objects. ### Significant Trends: This development highlights a significant trend in scientific research: the increasing reliance on and effectiveness of AI in tackling complex computational problems that were previously intractable. ### Notable Risks or Concerns: The primary challenge mentioned is **ensuring that AI results truly match the physical model**, a concern that the team's new paper addresses by demonstrating high accuracy. ### Material Financial Data: No material financial data is presented in this report.

Read original at Space.com →

A binary star system has two stars revolving around one center of mass.(Image credit: International Gemini Observatory/NOIRLab/NSF/AURA/J. da Silva (Spaceengine))This article was originally published at The Conversation. The publication contributed the article to Space.com's Expert Voices: Op-Ed & Insights.

Stars are the fundamental building blocks of our universe. Most stars host planets, like our Sun hosts our solar system, and if you look more broadly, groups of stars make up huge structures such as clusters and galaxies. So before astrophysicists can attempt to understand these large-scale structures, we first need to understand basic properties of stars, such as their mass, radius and temperature.

But measuring these basic properties has proved exceedingly difficult. This is because stars are quite literally at astronomical distances. If our Sun were a basketball on the East Coast of the U.S., then the closest star, Proxima, would be an orange in Hawaii. Even the world’s largest telescopes cannot resolve an orange in Hawaii.

Measuring radii and masses of stars appears to be out of scientists’ reach.Enter binary stars. Binaries are systems of two stars revolving around a mutual center of mass. Their motion is governed by Kepler’s harmonic law, which connects three important quantities: the sizes of each orbit, the time it takes for them to orbit, called the orbital period, and the total mass of the system.

I’m an astronomer, and my research team has been working on advancing our theoretical understanding and modeling approaches to binary stars and multiple stellar systems. For the past two decades we’ve also been pioneering the use of artificial intelligence in interpreting observations of these cornerstone celestial objects.

Measuring stellar massesAstronomers can measure orbital size and period of a binary system easily enough from observations, so with those two pieces they can calculate the total mass of the system. Kepler’s harmonic law acts as a scale to weigh celestial bodies.Think of a playground seesaw. If the two kids weigh about the same, they’ll have to sit at about the same distance from the midpoint.

If, however, one child is bigger, he or she will have to sit closer, and the smaller kid farther from the midpoint.Breaking space news, the latest updates on rocket launches, skywatching events and more!It’s the same with stars: The more massive the star in a binary pair, the closer to the center it is and the slower it revolves about the center.

When astronomers measure the speeds at which the stars move, they can also tell how large the stars’ orbits are, and as a result, what they must weigh.A close binary star system happens when several planets orbit the brighter star out of the pair. (Image credit: Robin Dienel, courtesy of the Carnegie Institution for Science)Measuring stellar radiiKepler’s harmonic law, unfortunately, tells astronomers nothing about the radii of stars.

For those, astronomers rely on another serendipitous feature of Mother Nature.Binary star orbits are oriented randomly. Sometimes, it happens that a telescope’s line of sight aligns with the plane a binary star system orbits on. This fortuitous alignment means the stars eclipse one another as they revolve about the center.

The shapes of these eclipses allow astronomers to find out the stars’ radii using straightforward geometry. These systems are called eclipsing binary stars.More than half of all Sun-like stars are found in binaries, and eclipsing binaries account for about 1% to 2% of all stars. That may sound low, but the universe is vast, so there are lots and lots of eclipsing systems out there – hundreds of millions in our galaxy alone.

By observing eclipsing binaries, astronomers can measure not only the masses and radii of stars but also how hot and how bright they are.An illustration showing a binary star pair in the Auriga constellation. The two stars are roughly the same mass and diameter and around every 47 hours one of the stars partially eclipses the other as seen from Earth.

(Image credit: Pablo Carlos Budassi)Complex problems require complex computingEven with eclipsing binaries, measuring the properties of stars is no easy task. Stars are deformed as they rotate and pull on each other in a binary system. They interact, they irradiate one another, they can have spots and magnetic fields, and they can be tilted this way or that.

To study them, astronomers use complex models that have many knobs and switches. As an input, the models take parameters – for example, a star’s shape and size, its orbital properties, or how much light it emits – to predict how an observer would see such an eclipsing binary system.Computer models take time.

Computing model predictions typically takes a few minutes. To be sure that we can trust them, we need to try lots of parameter combinations – typically tens of millions.This many combinations requires hundreds of millions of minutes of compute time, just to determine basic properties of stars. That amounts to over 200 years of computer time.

Computers linked in a cluster can compute faster, but even using a computer cluster, it takes three or more weeks to “solve,” or determine all the parameters for, a single binary. This challenge explains why there are only about 300 stars for which astronomers have accurate measurements of their fundamental parameters.

The models used to solve these systems have already been heavily optimized and can’t go much faster than they already do. So, researchers need an entirely new approach to reducing computing time.Using deep learningOne solution my research team has explored involves deep-learning neural networks. The basic idea is simple: We wanted to replace a computationally expensive physical model with a much faster AI-based model.

First, we computed a huge database of predictions about a hypothetical binary star – using the features that astronomers can readily observe – where we varied the hypothetical binary star’s properties. We are talking hundreds of millions of parameter combinations. Then, we compared these results to the actual observations to see which ones best match up.

AI and neural networks are ideally suited for this task.In a nutshell, neural networks are mappings. They map a certain known input to a given output. In our case, they map the properties of eclipsing binaries to the expected predictions. Neural networks emulate the model of a binary but without having to account for all the complexity of the physical model.

We train the neural network by showing it each prediction from our database, along with the set of properties used to generate it. Once fully trained, the neural network will be able to accurately predict what astronomers should observe from the given properties of a binary system.Compared to a few minutes of runtime for the physical model, a neural network uses artificial intelligence to get the same result within a tiny fraction of a second.

Two stars revolve around each other in a binary system. (Image credit: NASA/ESA Hubble Space Telescope WFPC2)Reaping the benefitsA tiny fraction of a second works out to about a millionfold runtime reduction. This brings the time down from weeks on a supercomputer to mere minutes on a single laptop.

It also means that we can analyze hundreds of thousands of binary systems in a couple of weeks on a computer cluster.This reduction means we can obtain fundamental properties – stellar masses, radii, temperatures and luminosities – for every eclipsing binary star ever observed within a month or two.

The big challenge remaining is to show that AI results really give the same results as the physical model.This task is the crux of my team’s new paper. In it we’ve shown that, indeed, the AI-driven model yields the same results as the physical model across over 99% of parameter combinations. This result means the AI’s performance is robust.

Our next step? Deploy the AI on all observed eclipsing binaries.Best of all? While we applied this methodology to binaries, the basic principle applies to any complex physical model out there. Similar AI models are already speeding up many real-world applications, from weather forecasting to stock market analysis.

This article is republished from The Conversation under a Creative Commons license. Read the original article.Join our Space Forums to keep talking space on the latest missions, night sky and more! And if you have a news tip, correction or comment, let us know at: community@space.com.Andrej Prša is a professor of Astrophysics and Planetary Science at Villanova University