University of Delaware
Department of Physics and Astronomy
Biden School of Public Policy and Administration
Data Science Institute
Rubin Observatory Construction Project - Deputy Project Scientist
Rubin Transients and Variable Stars Science Collaboration
federica bianco - Associate Professor
(she/her)
This is a living land acknowledgement developed in consultation with tribal leadership of Poutaxet, what is now known as the “Delaware Bay,” including: the Lenape Indian Tribe of Delaware, the Nanticoke Indian Tribe, and the Nanticoke Lenni-Lenape Tribal Nation in 2021. We thank these leaders for their generosity.
The University of Delaware occupies lands vital to the web of life for Lenni Lenape and Nanticoke, who share their ancestry, history, and future in this region. UD has financially benefited from this regional occupation as well as from Indigenous territories that were expropriated through the United States land grant system. European colonizers and later the United States forced Nanticoke and Lenni Lenape westward and northward, where they formed nations in present-day Oklahoma, Wisconsin, and Ontario, Canada. Others never left their homelands or returned from exile when they could. We express our appreciation for ongoing Indigenous stewardship of the ecologies and traditions of this region. While the harms to Indigenous people and their homelands are beyond repair, we commit to building right relationships going forward by collaborating with tribal leadership on actionable institutional steps.
Time domain astrophysics at a glance
Leading the Rubin LSST army of volunteers
Rubin LSST projects at FASTLab
At the intersection of astrophysics and Public Policy: From Light Echoes to Pollution Plumes
Data skills for good: COVID response support in Delaware
https://www.youtube.com/watch?v=qc_iscV1uA0
Bulding a legacy: the Vera C. Rubin Obsrvatory and LSST
FASTLa: AI applications to astrophysics and across disciplines
The immutable skies
Bartolomeu Velho, 1568 (Bibliothèque Nationale, Paris)
1549 Oronce Fine, France
From Flammarion's Astronomie Populaire (1880): in Scania, Denmark
Workshop of Diebold Lauber unknown artist, ca.1450
cepheid
GRB Afterglows
AGN
←Dimmer Brighter →
cepheid
Circa 1900
maybe 10 years ago
cepheid
GRB Afterglows
AGN
cepheid
GRB Afterglows
AGN
today
cepheid
GRB Afterglows
AGN
cepheid
GRB Afterglows
AGN
cepheid
GRB Afterglows
AGN
?
Will we discover new physics?
A comparative assessment of LSST potential surveys in the discovery of unknown unknowns
Vera C. Rubin Observatory:
LSST Science Drivers
Probing Dark Energy and Dark Matter
image credit ESO-Gaia
LSST Science Drivers
Mapping the Milky Way and Local Volume
via resolved stellar population
An unprecedented inventory of the Solar System from threatening NEO to the distant Oort Cloud
LSST Science Drivers
LSST Science Drivers
image credit: ESA-Justyn R. Maund
Exploring the Transients and Variable Universe
10M alerts every night shared with the world
60 seconds after observation
To accomplish this, we need:
1) a large telescope mirror to be sensitive - 8m (6.7m)
2) a large field-of-view for sky-scanning speed - 10 deg2
3) high spatial resolution, high quality images - 0.2''/pixels
4) process images in realtime and offline to produce live alerts and catalogs of all 37B objects
Objective: provide a science-ready dataset to transform the 4 key science area
2026
sensitivity
area of sky surveyed with 1 image
Resolution
10 (3.2 Gpx)
8
9
7
6
2M 3,200 Gigapixel images in 10 years -about 60 PB of data
Rubin Field of View: 10deg square
LIGO/VIRGO GW area of localization ~100deg square
Ursa Minor: 255.86 square degrees
S190425z 18% of the sky localization
At this level of precision,everything is variable, everything is blended, everything is moving.
SDSS
LSST-like HSC composite
Field of View' Image resolution' DDFs' Standard visit' Photometric precision' Photometric accuracy' Astrometric precision' Astrometric accuracy' |
9.6 sq deg 0.2'' (seeing limited) 5 DDF 30 sec 5 mmag 10 mmag 10 mas 50 mas |
' requirement: ls.st/srd
SDSS 2x4 arcmin sq griz
MYSUC (Gawiser 2014) 1 mag shallower than LSST coadds
u,g,r,i,z,y | |
---|---|
Photometric filters' saturation limit' # visits* mag single image* mag coadd* Nominal cadence |
u, g, r, i, z, y ~15, 16, 16, 16, 15, 14 53, 70, 185, 192, 168, 165 23.34, 23.2, 24.05, 23.55 22.03 25.4, 26.9, 27.0, 26.5, 25.8, 24.9 2-3 visits per night |
At this level of precision,everything is variable, everything is blended, everything is moving.
' requirement: ls.st/srd
Site: Cerro Pachon, Chile
Funding: US NSF + DOE
Status: final phases of construction - completion expected 2025
September 2016
Fabruary 2020
May 2022
November 2022
May 2022
May 2022 - Telescope Mount Assembly
18
late 2024-
early 2025
mid 2025
~2 years
from now
First data release ~3y from now
alerts build up
LSST survey strategy optimization
KN
distributions of time gaps in 76 OpSims
Rubin has involved the community to an unprecedented level in survey design this is a uniquely "democratic" process!
Survey Cadence Optimization Committee
Operation Simulator (OpSim)
simulates the catalog of LSST observations + observation properties
Metric Analysi Framwork (MAF)
Python API to interact with OpSims specifying science performance on a science case with a metric
Lynne Jones
Peter Yoachim
~100s simulations
~1000s MAFs
20+ peer review papers accepted several more under review and in preparation https://iopscience.iop.org/journal/0067-0049/page/rubin_cadence
Rubin has involved the community to an unprecedented level in survey design this is a uniquely "democratic" process!
2017
Rubin has involved the community to an unprecedented level in survey design this is a uniquely "democratic" process!
2019
Rubin has involved the community to an unprecedented level in survey design this is a uniquely "democratic" process!
2023
Rubin has involved the community to an unprecedented level in survey design this is a uniquely "democratic" process!
2024
LSST has profoundly changed the TDA infrastructure
To this day, transient astronomy heavily relies on spectra
To this day, transient astronomy heavily relies on spectra
To this day, transient astronomy heavily relies on spectra
collected rapidly!
described in ls.st/LDM-612
described in ls.st/LDM-612
world public!
10M alerts per night!! anything that changed by >5σ from "how the sky usually looks"
Discovery Engine
10M alerts/night
Community Brokers
target observation managers
BABAMUL
in 60 seconds:
Difference Image Analysis
in 60 seconds:
Difference Image Analysis + Bogus rejection
search
template
difference
-
=
96% accurate
Tatiana Acero-Cuellar, UNIDEL fellow, LSSTC data science fellow
search
template
difference
-
=
92% accurate
Tatiana Acero-Cuellar, UNIDEL fellow, LSSTC data science fellow
Saliency maps: what pixels matter?
Acero-Cuellar et al. DESC submitted
original paper : Karen Simonyan, Andrea Vedaldi, Andrew Zisserman 2013
· T. Nathan Mundhenk, Barry Y. Chen, Gerald Friedland 2019 ·
What is the network learning?
What can we learn from the AI?
search
template
difference
template
search
Tatiana Acero-Cuellar, UNIDEL fellow, LSSTC data science fellow
Willow Fox Fortino
UDelaware
When they go high, we go low... spectra classification at low resolution
Astrophysical spectra require the capture of enough photons at each wavelength:
large telescopes
long exposure times
bright objects
Rubin will see ~1000 SN every night!
Too many and too faint to study with traditional means, particularly spectra.
Lots of emphasis in new analysis techniques that rely on "Big Data"
Kepler satellite EB
LSST (simulated) EB
LSST Deep Drilling Fields
LSST Wide Fast Deep (main survey)
Siddarth Chiaini, UDelaware
Most classifiers for variable stars use Random Forest (not distance based)
In distance based classification, optimal distances can be found for the class of interest: flexible, customizable, efficient
https://arxiv.org/pdf/2403.12120.pdf
Astronomy and computing, under review
FASTlab Flash highlight
Willow Fox Fortino
UDelaware
When they go high, we go low
Classification power vs spectral resolution for SNe subtypes
Willow Fox Fortino
UDelaware
Optimal deep learning architectures for transients' spectral classification
As seen in Muthukrishna+2019
Willow Fox Fortino
UDelaware
Optimal deep learning architectures for transients' spectral classification
As seen in Muthukrishna+2019
Training a NN:
Results are based on test data, unseen in training
Willow Fox Fortino
UDelaware
Optimal deep learning architectures for transients' spectral classification
As seen in Muthukrishna+2019
Training a NN:
Results are based on test data, unseen in training
Willow has discovered that DASH was trainined with spectra of the same object in both training and testing
Willow Fox Fortino
UDelaware
Optimal deep learning architectures for transients' spectral classification
DASH model (M19)
Correcting training mistakes
(new baseline)
New Transformer model
(Fortino+ in prep)
(Transformer as in... ChatGPT)
Pies in the LSST sky
atmosphere-aided studies with LSST
dDCR color physical parameters
Quasars -> redshift
via spectral features falling in different observation bands
atmosphere-aided studies with LSST
Riley Clarke, UDelware
dM Flare energy
dDCR color Flare temperature
NSF Award #2308016
P.I. Bianco
Riley Clarke et al. 2024 submitted
AstroPhysical Journl Supplements
LSST ΔDCR detectability
Riley Clarke, UDelware
Stars that flare ΔDCR
LSST ΔDCR detectability
Riley Clarke, UDelware
Stars that flare ΔDCR
Riley Clarke, UDelware
Stars that flare ΔDCR
2018 Cadence White Paper
The violent and rapidly varying radiation from black holes, neutron stars, and white dwarfs makes them promising targets for high time resolution imaging.
The rotation, pulsation, and local accretion dynamics of these compact stellar remnants tends to occur on timescales ranging from seconds to milliseconds. Their extreme densities also makes them an excellent testing ground for nuclear, quantum, and gravitational physics.
Thomas and Kahn, 2018
Additional targets
cepheid
Continuous readout astronomical images for anomaly detection in ZTF
Shar Daniels, NSF GRFP Fellow 2024
new transformer models!
Light Echoes
Light Echoes
η-Carinae light echoes
Rest et al. (w Bianco) 2012Natur.482..375R
Light Echoes
η-Carinae light echoes
Frew 2004, Smith & Frew 2011
Light Echoes
η-Carinae light echoes
Light Echoes
η-Carinae light echoes
Xiaolong Li et al. 2022
LSSTC Catalyst Fellow, J. Hopkins
AILE: the first AI-based platform for the detection and study of Light Echoes
NSF Award #2108841
P.I. Bianco
Light Ecoes are rare strophsyical pheonomena and a near-pessimal problem for AI, but with as much data as LSST AI is a necessity
Testing the performancde os SAM on astronomical objects
Rodiat Ayinde
Lincoln University (PA)
NSF Award #2123264
P.I. Bianco
Multi-city Urban Observatory Network
Studying cities as complex systems through imaging data
Multi-city Urban Observatory Network
Studying cities as complex systems through imaging data
Multi-city Urban Observatory Network
From Light Echoes to Polluting Plumes
Pessimal AI problem:
Jessica Salcido, NYU
From Light Echoes to Polluting Plumes
Pessimal AI problem:
Jessica Salcido, NYU
reconstructed
next in sequence
PCA alligned difference
-
=
Jessica Salcido, NYU
Real Time detection of emerging plumes and other anomalies in city scapes
Somayeh Khakpash
Catalyst Fellow (Rutgers)
Autoencoders to generate computationally expensive caustic maps for quasar microlensing and infer physical parameters from the latent space
FASTlab Flash highlight
Plumes and heat in NIR
Plumes in hyperspectral imaging
"It has been invaluable to have predictions for the next week instead of having to panic about the next shift"
Dr. Somayeh Khakpash
LSSTC Catalyst Fellow, Rutgers
Rare classes will become common, but how do we know what we are looking at and classify different objects for sample studies?
Data-Driven Templates for stripped SESN
Research Inclusion: sonification of LSST lightcurves
Riley Clarke, UD grad student Sid Patel, UD undergrad summer research project
Sonification: Data → Sound
New way of understanding data
Gives access to people who cannot
interpret data visually
Sounds cool! Good for public outreach
Research Inclusion: sonification of LSST lightcurves
Rubin Rhapsodies
Research Inclusion: sonification of LSST lightcurves
Rubin Rhapsodies
thank you!
University of Delaware
Department of Physics and Astronomy
Biden School of Public Policy and Administration
Data Science Institute
federica bianco
fbianco@udel.edu
Diversity Equity Inclusion
We aspire to be an inclusive, equitable, and ultimately just group and we are working with renewed vigor in the wake of the recent event that exposed inequity and racism in our society to turning this aspiration into action.
what's in a name?
The first ground-based national US observatory named after a woman, Dr. Vera C. Rubin
VRO
In the first 10 years of its life Rubin will conduct the Legacy Survey of Space and Time or LSST