CCOR-1 (Compact CORonograph-1) is a space-based coronograph aboard a geostationary satellite GOES-19 owned by NOAA. Its goal is providing solar data used for space weather forecasting.
By covering the Sun's surface (photosphere), it allows to observe its atmosphere called corona. It is millions of times fainter than the Sun itself, its surface brightness roughly comparable to full Moon's. It is important to monitor the corona, as coronal mass ejections (CME) can damage power grids, interrupt GPS systems and cause damage to technology resulting in a cost of repair counted in millions or even billions of dollars.
The instrument's goal is obtaining white light images of the solar corona as well as tracking CMEs and downlinking the data within 30 minute latency. The data is then used to make a space weather forecast. CCOR's purpose is also replacing aging research coronographs like SOHO/LASCO or STEREO/COR.
It was launched on 25 June 2024 5:26 PM EDT using Falcon Heavy rocket from John F. Kennedy Space Center. On 19 September 2024 it obtained its first light image, however it was made public on 22 October. The instrument (and the entire satellite) was handed over to NOAA on 29 January 2025.
On 7 April 2025 it was declared an official operational satellite on GOES-East, located at 75.2ðW longitude.
It is on a geostationary orbit which means that the angular motion of the satellite is equal to Earth's, therefore the object seems to âÂÂhang" above a specific spot on the planet. This orbit is placed above the equator.
CCOR-1 was developed and tested by US Naval Research Laboratory (NRL). It is placed on a Sun Pointing Platform (SPS) specifically designed for solar instruments. It is mounted aside EXIS and SUVI.
Since the instrument is flying on geocentric orbit, it experiences eclipses once a day. Around 20 days before and after any equinox, the Earth eclipses half of the images. CCOR-1 performs a 180-degree roll maneuver called yawflip to decrease solar array stray light in the camera.
The list of requirements that the instrument has to follow is written below:
Note:
stands for solar surface brightness âÂÂ10.7 mag/arcsec
is Sun's radius = = 0.266ð. The FOV is measured at , counted from the outermost edge of the star.
CMEs are detected by PyCat â open-source software created by NOAA/SWPC and UK Met Office. It is a modernized version of older CAT. PyCat studies the morphology of the event from L1 files (check Ground Processing Algorithm below) and compares its appearance from different satellites. Using this data, it can calculate speed, mass and direction of CME.
In order for the raw images from the coronograph to be usable, they have to be processed upon being received. The data sent to the ground by SWPC is already compressed into FITS format files. CCOR-1 images have six processing levels.
First processing level is called L0. It is the raw readout of packets from the detector and metadata (header). From L0 two L0A files are assembled. These are inner FOV and outer FOV parts of image. After L0A images are combined and rotated so solar north is pointing upwards, a L0B file is created.
L0B then undergoes several processings. These are as follows:
These calibrations create L1A file. L1A serves as the source for creating models, i.e. earthshine and median background. Earthshine is computed from L1A and then used for subtraction from the image and that creates L1B. It is the only level available in real time.
CCOR_0A_20251002T000025_V00_N2.fits
CCOR_1A_20251002T000025_V00_NC.fits
CCOR_1B_20251002T000025_V00_NC.fits
CCOR_2_20251002T000025_V00_NC.fits
L1A is used for median background determination. A median background of the entire day is called Daily Median (DM). After that, a minimum background is calculated to mirror the slowly changing straylight and F-corona (F-corona is Sun's light reflected of dust particles). 14 days of median background create Monthly Minimal Background (MM), while 7 days is called Minimal background. L1 products then get processed by subtracting either to get L2 level. L2 binned to 2ÃÂ2 is L3.
CCOR-1 allows observations of near Sun comets, especially sungrazers. The first discovery was a Kreutz comet found by an US citizen scientist Robert Pickard on 11 February 2025. It was accompanied by two fragments.
To 28 May 2025, 47 comets were officially confirmed via NASA's Sungrazer Project program.