Fortune Favors the Prepared • Intelligence & Analysis
The Sky Is Being Watched: What Actually Happens If Something Is Coming
Hollywood has been telling this story for almost fifty years. The real version, the actual math, the real notification chain, and who is really watching, is less cinematic and more useful to know.
Bottom Line Up Front
There is no secret government program keeping a planet killing asteroid quiet. There is a real, documented, international detection and notification system, and it has already been tested once, in public, in 2025. The system has known gaps: a blind spot toward the sun, an overall first detection success rate estimated around one percent, and no binding international agreement on what any government would actually do once a threat was confirmed. Understanding those gaps, not the movie version, is what actually matters for preparedness planning.
1. The Version Hollywood Sold Us
The genre is nearly fifty years old. Meteor (1979) set the template: a large object on collision course, a scramble to build a response, a government slow to act. Nineteen years later, two studios released competing versions in the same summer. Armageddon gave audiences a Texas sized asteroid and a team of oil drillers turned astronauts. Deep Impact, released first, told a quieter and arguably more realistic story: a comet, a years long lead time, and a government that tells the public early, then manages the fallout of that disclosure. That contrast between the two 1998 films, spectacle versus disclosure, is really the whole debate in miniature.
More recent films have moved further from rescue fantasy. Greenland (2020) centers the public’s experience of evacuation and breakdown rather than the mission to stop the impact. Don’t Look Up (2021) is a direct satire of political and media failure to act on a confirmed, dated extinction level threat. The genre’s trend line is instructive on its own: the newer films trust institutions less, not more.
None of this is prediction. It is worth naming because it shapes what people expect a real event to look like, and the real system does not resemble either the 1998 spectacle model or the 2021 satire. It is slower, more bureaucratic, and more transparent than both.
2. The Actual Math
Object size drives everything. A rough scale, drawn from current planetary defense research:
| Object Size | Approximate Frequency | Consequence |
| About 3 meters | About once a year | Burns up in atmosphere, no threat |
| 18 to 20 meters (Chelyabinsk class) | Decades scale | Regional injury and damage if over a populated area |
| 140 meters and larger | Roughly once every 11,000 years | Significant regional to sub continental damage |
| Several kilometers (extinction class) | Roughly once every 10 million years | Global, civilization altering |
The 11,000 year figure for 140 meter and larger objects comes from a 2025 Planetary Science Journal study that modeled simulated near-Earth object populations against JPL’s Horizons ephemeris data. It is a statistical average across the whole population, not a countdown clock, which is exactly where public understanding tends to break down.
The 2024 YR4 case is the best recent example of how badly a raw percentage can be misread. Its estimated impact probability climbed from roughly one percent at first detection in January 2025 to a peak of 3.1 percent in mid February, then collapsed to 0.004 percent within days, and later fell below 0.00001 percent as more observations narrowed the object’s orbital uncertainty. Nothing about the asteroid changed in that window. Only the precision of the tracking data changed. Any single probability number reported early in an event should be read as provisional by default, not as a verdict.
3. Would They Actually Tell Us: The Real Notification Chain
There is a documented, if imperfect, answer to this question, and it does not involve a cover up. The International Asteroid Warning Network (IAWN), established following a 2013 United Nations Committee on the Peaceful Uses of Outer Space action and formally endorsed by UN resolution in 2023, exists specifically as the notification clearinghouse. Its threshold for issuing a warning is an impact probability greater than 1 percent within the next 20 years, for an object larger than roughly 10 meters. That threshold has been reached exactly once since IAWN’s founding: during the 2024 YR4 event, when the United Nations Office for Outer Space Affairs formally notified national stakeholders including the United States Space Force.
On the domestic side, the United States has an actual written playbook: the federal Report on Near-Earth Object Impact Threat Emergency Protocols, developed under the National Science and Technology Council. It describes a flow that starts with an initial coordination call among federal emergency management officials, proceeds through Emergency Support Function 15 (public affairs) for the first public messaging, and separately tasks the Department of State and NASA with a priority list of foreign governments to notify. The same document is candid about the honest limitation in this entire system: there are no firm, binding commitments from any spacefaring nation as to what response would actually be mounted against a confirmed threat. The process for finding out exists. The guarantee of a coordinated response does not.
The overarching federal policy tying all of this together is the 2023 NSTC National Preparedness Strategy and Action Plan for Near-Earth Object Hazards and Planetary Defense, which explicitly folds interstellar objects into the same detection, modeling, and interagency coordination goals as ordinary near-Earth asteroids.
One more structural point worth understanding: as of the most recent published estimate, only about 44 percent of near-Earth objects in the 140 meter and larger size class have actually been found. A notification system can only notify on what has been detected. That gap is the subject of the next section.
4. Who Is Actually Watching
It is a common assumption that a threat like this would first surface inside a classified government channel. In practice, the detection and cataloging backbone is largely non-governmental and international by design. IAWN itself is not a government agency. It is a UN endorsed collaboration of more than 60 signatory observatories, universities, and space institutions worldwide, pooling ground and space based detection assets.
The actual global clearinghouse for confirming a new discovery is the International Astronomical Union’s Minor Planet Center, an independent scientific body, not a national defense agency. Any observatory, including well equipped amateur trackers, can submit observations into that same pipeline. This is precisely how the interstellar object 3I/ATLAS was handled in 2025: discovered by the NASA funded but independently operated ATLAS survey telescope in Chile, it triggered the first IAWN monitoring campaign ever run against an interstellar visitor, and prompted a large scale planetary defense communication drill even though officials confirmed early on that there was no collision risk. The system, in other words, has already had a live dress rehearsal, on an actual object, with the public watching in real time.
The newest asset in this network came online in 2025 and 2026: the Vera C. Rubin Observatory in Chile, jointly funded by the National Science Foundation and the Department of Energy. In its earliest, pre-survey data alone, Rubin submitted more than 11,000 new asteroid detections to the Minor Planet Center, including 33 previously unknown near-Earth objects. None of the objects found so far pose a threat. The significance is capability, not any specific finding: Rubin surveys at roughly six times the sensitivity of prior asteroid search systems, and its planned ten year survey is expected to nearly double the known population of hazardous sized (140 meter plus) near-Earth objects, pushing the known catalog from about 44 percent complete toward something closer to 70 percent.
5. The Detection Gap, Told Through One Real Night
The honest weak point in the entire system is geometry, not competence. Ground based telescopes cannot see objects approaching from the direction of the sun; the glare defeats them. Current systems also only achieve final approach detection in an estimated one percent of cases overall, a figure that gets worse for smaller objects. The overall population of known near-Earth objects has an estimated 89 to 99 percent completeness for anything a kilometer or larger, but completeness drops sharply as object size drops.
February 15, 2013 is the case study that makes this concrete. Astronomers were closely tracking a known 40 meter asteroid, 367943 Duende, on a well predicted, non threatening close approach to Earth that same day, a genuine planetary defense success story at the time. Sixteen hours before Duende’s flyby, an entirely separate and completely undetected 18 meter object entered the atmosphere over Chelyabinsk, Russia, arriving from the sun’s direction where no telescope was looking. It injured roughly 1,500 people and damaged more than 7,000 buildings. The tracked object and the striking object were unrelated, and the one that actually hit was the one nobody saw coming, arriving from the exact blind spot every ground based system shares. That juxtaposition, a success and a miss on the same day, is a more honest planetary defense story than anything a studio has produced.
6. Why You Need to Know This
A fair question at this point is why a low probability hazard, once every 11,000 years for anything regionally significant, deserves a place in a personal preparedness plan at all. The honest answer is that probability is only half the risk equation. The other half is consequence, and for this specific hazard the consequence side is about as high as it gets: a regional strike removes infrastructure, food supply chains, and communications across an area the size of a state or larger, with no local mutual aid to draw on because the surrounding region is affected too. Low frequency, high consequence events are exactly the category that conventional planning tends to under-weight, because the low frequency number is easier to remember than the consequence number.
This is also precisely why the hazard belongs inside your existing plan rather than a separate one built just for it. The failure modes an NEO strike produces, loss of communications, disrupted supply chains, mass displacement, regional infrastructure damage, are the same failure modes produced by a major hurricane, a large scale grid failure, or a significant earthquake. The response actions are largely the same too. The value of reading about this hazard is not memorizing an asteroid specific checklist. It is confirming that your general all hazards plan actually holds up against a scenario with a longer warning window but a wider blast radius than most people plan for.
If you have not run a structured assessment of your own household’s readiness against low frequency, high consequence scenarios like this one, that is the right next step, not researching asteroid trivia. Start with the Personal Preparedness Assessment to establish where your actual gaps are before layering in any hazard specific planning on top.
7. Reading This Through the FFTP Standing Conditions Framework
Regular readers of the Daily Threat Report already track a set of standing conditions each cycle: DEFCON, COGCON, FPCON, CYBERCON, and two conditions proprietary to this platform, COMCON and PREP-CON. A near-Earth object notification does not map onto any single one of those, but it is worth understanding how it would move through a framework readers already use.
An IAWN notification functions much like a DTR standing condition escalation: it is issued only when a defined, numeric threshold is crossed, in this case an impact probability above 1 percent within a 20 year window for an object 10 meters or larger, exactly the kind of hard trigger this platform uses for its own COMCON and PREP-CON escalation criteria rather than a subjective judgment call. The core discipline is the same one this platform applies every cycle: report the threshold that was actually crossed, not the worst case headline number.
For household level planning purposes, an NEO notification event should be read against your own PREP-CON posture rather than treated as a standalone crisis category. A confirmed IAWN threshold crossing, on an object with a multi year or longer warning window, is realistically a PREP-CON 4 (Elevated Watch) level input at most, informational and worth monitoring, not an immediate action trigger. It would only justify moving toward PREP-CON 3 (Elevated) or below if follow up observations increased both the probability and the confidence in a short warning window, which, per the Torino Impact Hazard Scale used by astronomers internationally, would itself be publicly visible as the event moved into that scale’s yellow or orange categories. The Family Emergency Plan Workbook actions already tied to each PREP-CON level, communications continuity, supply posture, evacuation readiness, apply here without modification. This is a category of hazard best absorbed into existing all hazards planning, not a reason to build a separate plan.
From the Continuity Chronicles
Readers of The Continuity Chronicles techno-thriller series, The Meadow Protocol, The Brush, Unassigned Authority, and the fourth book now in development, will recognize this same pattern: real institutional machinery that is slower, more procedural, and more transparent than fiction usually allows, with the actual risk sitting quietly in the gaps between agencies rather than in any single dramatic failure. Explore the series at thecontinuitychronicles.net.
Sources: NASA’s Center for Near-Earth Object Studies; the 2023 NSTC National Preparedness Strategy and Action Plan for Near-Earth Object Hazards and Planetary Defense; the Report on Near-Earth Object Impact Threat Emergency Protocols; the International Asteroid Warning Network; the IAU Minor Planet Center; NSF-DOE Vera C. Rubin Observatory public releases; and the Planetary Science Journal (2025).
Semper Paratus, Semper Gumby.