Machine Learning rekonstruiert aus den EHT-Daten ein neues Bild.
M87s Foto[{“ attribute=““>black hole has been enhanced using a machine learning technique called PRIMO, providing a more accurate representation and allowing for improved determinations of its mass and physical parameters.
The iconic image of the supermassive black hole at the center of M87—sometimes referred to as the “fuzzy, orange donut”—has gotten its first official makeover with the help of machine learning. The new image further exposes a central region that is larger and darker, surrounded by the bright accreting gas shaped like a “skinny donut.” The team used the data obtained by the Event Horizon Telescope (EHT) collaboration in 2017 and achieved, for the first time, the full resolution of the array.
In 2017, the EHT collaboration used a network of seven pre-existing telescopes around the world to gather data on M87, creating an “Earth-sized telescope.” However, since it is infeasible to cover the Earth’s entire surface with telescopes, gaps arise in the data—like missing pieces in a jigsaw puzzle.
“With our new machine learning technique, PRIMO, we were able to achieve the maximum resolution of the current array,” says lead author Lia Medeiros of the Institute for Advanced Study. “Since we cannot study black holes up close, the detail of an image plays a critical role in our ability to understand its behavior. The width of the ring in the image is now smaller by about a factor of two, which will be a powerful constraint for our theoretical models and tests of gravity.”
PRIMO, which stands for principal-component interferometric modeling, was developed by EHT members Lia Medeiros (Institute for Advanced Study), Dimitrios Psaltis (Georgia Tech), Tod Lauer (NOIRLab), and Feryal Özel (Georgia Tech). Their publication, “The Image of the M87 Black Hole Reconstructed with PRIMO,” was published today (April 13) in The Astrophysical Journal Letters.
“PRIMO is a new approach to the difficult task of constructing images from EHT observations,” said Lauer. “It provides a way to compensate for the missing information about the object being observed, which is required to generate the image that would have been seen using a single gigantic radio telescope the size of the Earth.”
PRIMO relies on dictionary learning, a branch of machine learning which enables computers to generate rules based on large sets of training material. For example, if a computer is fed a series of different banana images—with sufficient training—it may be able to determine if an unknown image is or is not a banana. Beyond this simple case, the versatility of machine learning has been demonstrated in numerous ways: from creating Renaissance-style works of art to completing the unfinished work of Beethoven. So how might machines help scientists to render a black hole image? The research team has answered this very question.
With PRIMO, computers analyzed over 30,000 high-fidelity simulated images of black holes accreting gas. The ensemble of simulations covered a wide range of models for how the black hole accretes matter, looking for common patterns in the structure of the images. The various patterns of structure were sorted by how commonly they occurred in the simulations, and were then blended to provide a highly accurate representation of the EHT observations, simultaneously providing a high fidelity estimate of the missing structure of the images. A paper pertaining to the algorithm itself was published in The Astrophysical Journal on February 3, 2023.
“We are using physics to fill in regions of missing data in a way that has never been done before by using machine learning,” added Medeiros. “This could have important implications for interferometry, which plays a role in fields from exo-planets to medicine.”
Übersicht über die Simulationen, die für das PRIMO-Algorithmus-Trainingsset generiert wurden. Bildnachweis: Medeiros et al. 2023
Das Team bestätigte, dass das neu bereitgestellte Bild mit den EHT-Daten und mit theoretischen Vorhersagen übereinstimmt, einschließlich des hellen Emissionsrings, der erwartet wird, wenn heißes Gas in das Schwarze Loch fällt. Um ein Bild zu erstellen, muss die richtige Form der fehlenden Informationen angenommen werden, und PRIMO tat dies, indem es auf der Entdeckung von 2019 aufbaute, dass das Schwarze Loch M87 in großen Details genauso aussah wie vorhergesagt.
„Fast vier Jahre nach der Enthüllung des ersten horizontalen Bildes eines Schwarzen Lochs durch EHT im Jahr 2019 haben wir einen weiteren Meilenstein gesetzt und ein Bild erstellt, das zum ersten Mal die volle Auflösung der Matrix nutzt“, sagte Psaltis. „Die neuen maschinellen Lerntechniken, die wir entwickelt haben, bieten eine hervorragende Gelegenheit für unsere gemeinsame Arbeit, die Physik von Schwarzen Löchern zu verstehen.“
Das neue Bild sollte zu genaueren Bestimmungen der Masse des Schwarzen Lochs M87 und der physikalischen Parameter führen, die sein derzeitiges Aussehen bestimmen. Die Daten bieten Forschern auch die Möglichkeit, Ereignishorizontalternativen stärker einzuschränken (basierend auf einer geringeren dunklen zentralen Helligkeit) und robustere Tests der Schwerkraft durchzuführen (basierend auf einer schmaleren Ringgröße). PRIMO kann auch auf zusätzliche EHT-Beobachtungen angewendet werden, einschließlich Beobachtungen von Sgr A*, dem zentralen Schwarzen Loch in unserer Region.[{“ attribute=““>Milky Way galaxy.
M87 is a massive, relatively nearby, galaxy in the Virgo cluster of galaxies. Over a century ago, a mysterious jet of hot plasma was observed to emanate from its center. Beginning in the 1950s, the then new technique of radio astronomy showed the galaxy to have a compact bright radio source at its center. During the 1960s, M87 had been suspected to have a massive black hole at its center powering this activity. Measurements made from ground-based telescopes starting in the 1970s, and later the Hubble Space Telescope starting in the 1990s, provided strong support that M87 indeed harbored a black hole weighing several billion times the mass of the Sun based on observations of the high velocities of stars and gas orbiting its center. The 2017 EHT observations of M87 were obtained over several days from several different radio telescopes linked together at the same time to obtain the highest possible resolution. The now iconic “orange donut” picture of the M87 black hole, released in 2019, reflected the first attempt to produce an image from these observations.
“The 2019 image was just the beginning,” stated Medeiros. “If a picture is worth a thousand words, the data underlying that image have many more stories to tell. PRIMO will continue to be a critical tool in extracting such insights.”
Reference: “The Image of the M87 Black Hole Reconstructed with PRIMO” by Lia Medeiros, Dimitrios Psaltis, Tod R. Lauer and Feryal Özel3, 13 April 2023, The Astrophysical Journal Letters.
DOI: 10.3847/2041-8213/acc32d
Development of the PRIMO algorithm was enabled through the support of the National Science Foundation Astronomy and Astrophysics Postdoctoral Fellowship.
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