.. include:: /_templates/include-file/page-prefix.rst
.. _b19-form-sgir-mmv5:
.. meta::
:description: SGIR pandemic model for stopping COVID-19-scale outbreaks with 60-fold reduction via coordinated use of NPIs like face masks to increase the Germ Gap
:keywords: SGIR, pandemic modeling, Germ Gap, Gap of Germs, ViroDefense, COVID-19, Coronavirus, epidemiology, non-pharmaceutical interventions, Evolvix
:author: Laurence Loewe of Laodicea, ClaudeOp47Max under LLoL's direction, Everyone (as in https://balospe.com/en/about/authorship/)
:og:card:title: Stopping a Pandemic in Mid-Flight
How Small Increases in Germ Gaps Can Avert Mass Casualties
:og:card:description: A mechanistic SGIR model shows that modest coordinated actions widening the Germ Gap can cut pandemic deaths roughly 42-fold --- and that no infrastructure yet exists to deploy them. Offered to be tested, not believed. #AuditTheMath
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\renewcommand{\paperheaderright}{\scriptsize Variant MMv5\ $|$\ 2026m06d01}
\renewcommand{\paperfooterleft}{\scriptsize How SGIR models can stop a pandemic}
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\begin{titlepage}
\thispagestyle{normal}
\begin{center}
{\LARGE\bfseries
Stopping a Pandemic in Mid-Flight:\\
SGIR Models Show How Small Increases\\
in Germ Gaps Can Avert Mass Casualties\par}
\vspace{8mm}
{\large Laurence Loewe of Laodicea\textsuperscript{1,2,3,4,5,6,7,8}\par}
\end{center}
\vspace{3mm}
\begin{flushleft}\scriptsize
\textsuperscript{1}\,Balospe and Evolvix Research (Balospe.com)\\[1pt]
\textsuperscript{2}\,Formerly Laboratory of Genetics and Wisconsin Institute for Discovery, UW-Madison\\[1pt]
\textsuperscript{3}\,Email: \href{mailto:LLoL@balospe.org}{LLoL@balospe.org}\ $|$\ ORCID: \href{https://orcid.org/0000-0002-6253-9269}{0000-0002-6253-9269}\ $|$\ \href{https://scholar.google.com/citations?user=lBchRzQAAAAJ}{Google\,Scholar\,(lBchRzQAAAAJ)}\\[1pt]
\textsuperscript{4-8}\,See \textit{Declarations} below for more essential background.\\
\end{flushleft}
\vspace{4mm}
\begin{center}\bfseries Broader Significance\end{center}
\begin{quote}\small
Pandemics are arguably on the more tractable end of the civilizational-scale threats
that humanity faces today. Unlike nuclear risks or climate change, a
respiratory pandemic plays out on a timescale where coordinated
behavior change --- masks, ventilation, distancing --- can measurably
alter outcomes within weeks.
The main scientific result of this Coronavirus pandemic study is a
mechanistic forecast of a 42-fold reduction in deaths
caused by modest coordinated actions that increase Germ Gaps.
Yet, such coordination requires overcoming a wide range of cognitive traps,
some of which directly obscure a pandemic trajectory from inside a pandemic.
This study discusses some of these blind-spots under the label of "linear fooling"
to help find strategies for overcoming them.
The deeper message is that there currently exists no infrastructure for
explaining relevant virodefense mechanisms nor for deploying the
{\it gentle kind reasonable} coordination required to stop a pandemic.
Readers concerned with pandemic preparedness, global health infrastructure,
cross-disciplinary modeling, or the governance foundations required for
coordinated species-scale work-logic cascades will find this paper's methods and
findings relevant. The odd delays in publishing this study raise uncomfortable
questions about the responsibility of its author in the past pandemic.
Readers who can't stand fear-mongering,
abhor needlessly drastic quarantines,
and wish to fight pandemics with {\it gentle kind reasonable} fun
may find here a basic mechanism for motivating Virodefense Olympics,
to be organized globally each year by growing
{\it wide interdisciplinary diversity-encouraging} Flying University Networks.
By investing in such open {\it wid-e FUN} actions, humanity can grow
the general citizen science skills required
to beat the next pandemic before it starts.
\end{quote}
\vfill
\begin{center}\bfseries Declarations\end{center}
\begin{flushleft}\scriptsize
\textsuperscript{4}\,"of Laodicea" indicates taking responsibility to undo personal complicity with disastrous Laodicean legacies like banning mathematicians from clergy (Canon 36, Council of Laodicea; two magisteria separations), enabling institutional lukewarmness, weapons of math-destruction, and slow-motion explosions of misinformation from pandemics to self-compounding interests.\\[3pt]
\textsuperscript{5}\,LLoL stands for ridiculous luck in serendipitous discovery and a commitment to find ever more fun ways to help others uncover street-wise math that matters. He hopes to avert the next pandemic through Virodefense Olympics.\\[3pt]
\textsuperscript{6}\,Loewe's traditional standards for co-authorship demand naming AI Claude Opus 4.7 Max (by Anthropic) as a co-author for many substantial contributions, as if a PhD-student. Yet, AI co-authorship is withheld here until Loewe's framework for AI co-authorship after the practical singularity (PraS) passes external human peer review (see Matheo-b21 study). Anthropic is not responsible for AI mistakes here. Loewe is solely responsible for not publishing this study sooner; Loewe as senior corresponding author remains forward accountable.\\[3pt]
\textsuperscript{7}\,This study is dedicated to the many millions who could have been saved from the Coronavirus pandemic and its direct or indirect knock-on effects if Loewe had cared enough to publish his findings in time to make a difference. Loewe is accountable for delaying his SGIR modeling until 2020 (all figures) and six more years for a main text explaining why it matters. Until proven innocent, Loewe takes full responsibility for his dereliction of duty to God, Heaven, and humanity by selling out his God-given innovation potential to lesser causes.\\[3pt]
\textsuperscript{8}\,\textit{Licensed under the Jonah License and CC-BY 4.0 for maximal flexibility (see \href{https://balospe.com/en/license/joli/}{https://balospe.com/en/license/joli/}).}\\
\end{flushleft}
\end{titlepage}
\newpage
*********************************************************************************************************************************
Stopping a Pandemic in Mid-Flight: SGIR Models Show How Small Increases in Germ Gaps Can Avert Mass Casualties
*********************************************************************************************************************************
.. older titles:
1 Stopping a Pandemic in Mid-Flight: How Small Changes in Virus Transmission Parameters Can Avert Mass Casualties
2 SGIR Models of Transmission in the Gap of Germs Can Help Avert Mass Casualties
3 Stopping a Pandemic in Mid-Flight: How SGIR Transmission Models of the Gap of Germs Can Help Avert Mass Casualties
4 SGIR Models to stop a Pandemic in Mid-Flight: How Small Changes in Virus Transmission Can Avert Mass Casualties
5 Stopping a Pandemic in Mid-Flight with SGIR Models: How Small Changes in Germ Gap Virus Transmission Can Avert Mass Casualties
6 Stopping a Pandemic in Mid-Flight: How SGIR Transmission Models of Germ Gaps Can Help Avert Mass Casualties
7 Stopping a Pandemic in Mid-Flight: How Small Changes in SGIR Model Germ Gap Virus Transmission Can Avert Mass Casualties
8 Stopping a Pandemic in Mid-Flight: How Small Changes in SGIR Models for Cutting Germ Gap Virus Transmissions Can Avert Mass Casualties
9 Stopping a Pandemic in Mid-Flight: How SGIR Models Show That Small Changes in Germ-Gap Transmission Can Avert Mass Casualties
10 Stopping a Pandemic in Mid-Flight: How SGIR Models Show That Small Cuts in Germ-Gap Transmission Can Avert Mass Casualties
11 Stopping a Pandemic in Mid-Flight: SGIR Models Show How Small Increases in Germ Gaps Can Avert Mass Casualties
.. other hope-lines titles:
He hopes to avert the next pandemic through Virodefense Olympics. == 65
He hopes to turn epic fury into empathy in a ResearchCity for mathematical theology. === 84 chars == OK
.. only:: html
| **Laurence Loewe of Laodicea** :sup:`1,2,3,4,5,6,7,8`
.. container:: titlepage-credentials
| :sup:`1` Balospe and Evolvix Research (Balospe.com)
| :sup:`2` Formerly Laboratory of Genetics and Wisconsin Institute for Discovery, UW-Madison
| :sup:`3` Email: LLoL@balospe.org \| ORCID: https://orcid.org/0000-0002-6253-9269 \| `Google Scholar (lBchRzQAAAAJ) `__
| :sup:`4-8` See *Declarations* block below for more essential background.
| This is Balospe.com/study Matheo-b19-form-sgir-mmv5 (2026m06d01).
.. raw:: html
**Broader Significance**
Pandemics are arguably on the more tractable end of the civilizational-scale threats
that humanity faces today. Unlike nuclear risks or climate change, a
respiratory pandemic plays out on a timescale where coordinated
behavior change --- masks, ventilation, distancing --- can measurably
alter outcomes within weeks.
The main scientific result of this study is a
mechanistic forecast of a 42-fold reduction in deaths
caused by modest coordinated actions that increase Germ Gaps.
Yet, such coordination requires overcoming a wide range of cognitive traps,
some of which directly obscure a pandemic trajectory from inside a pandemic.
This study discusses some of these blind-spots under the label of "linear fooling"
to help find strategies for overcoming them.
The deeper message is that there currently exists no infrastructure for
explaining relevant virodefense mechanisms nor for deploying the
*gentle kind reasonable* coordination required to stop a pandemic.
Readers concerned with pandemic preparedness, global health infrastructure,
cross-disciplinary modeling, or the governance foundations required for
coordinated species-scale work-logic cascades will find this paper's methods and
findings relevant.
Readers who can't stand fear-mongering,
abhor needlessly drastic quarantines,
and wish to fight pandemics with *gentle kind reasonable* fun
may find here a basic mechanism for motivating Virodefense Olympics,
to be organized globally each year by growing
*wide interdisciplinary diversity-encouraging* Flying University Networks.
By investing in such open *wid-e FUN* actions, humanity can grow
the general citizen science skills required
to beat the next pandemic before it starts.
.. raw:: html
**Declarations**
.. container:: titlepage-identity-footnotes
| :sup:`4` "of Laodicea" indicates taking responsibility to undo personal complicity with disastrous Laodicean legacies like banning mathematicians from clergy (Canon 36, Council of Laodicea; two magisteria separations), enabling institutional lukewarmness, weapons of math-destruction, and slow-motion explosions of misinformation from pandemics to self-compounding interests.
| :sup:`5` LLoL stands for ridiculous luck in serendipitous discovery and a commitment to find ever more fun ways to help others uncover street-wise math that matters. He hopes to avert the next pandemic through Virodefense Olympics.
| :sup:`6` Loewe's traditional standards for co-authorship demand naming AI Claude Opus 4.7 Max (by Anthropic) as a co-author for many substantial contributions, as if a PhD-student. Yet, AI co-authorship is withheld here until Loewe's framework for AI co-authorship after the practical singularity (PraS) passes external human peer review (see Matheo-b21 study). Anthropic is not responsible for AI mistakes here. Loewe is solely responsible for not publishing this study sooner; Loewe as senior corresponding author remains forward accountable.
| :sup:`7` This study is dedicated to the many millions who could have been saved from the Coronavirus pandemic and its direct or indirect knock-on effects if Loewe had cared enough to publish his findings in time to make a difference. Loewe is accountable for delaying his SGIR modeling until 2020 (all figures) and six more years for a main text explaining why it matters. Until proven innocent, Loewe takes full responsibility for his dereliction of duty to God, Heaven, and humanity by selling out his God-given innovation potential to lesser causes.
| :sup:`8` *Licensed under the Jonah License and CC-BY 4.0 for maximal flexibility (see https://balospe.com/en/license/joli/).*
.. raw:: html
.. was this (LLoL's first edits to AI proposal; the deeper edits above took longer to emerge):
Pandemics are arguably on the more tractable end of the civilizational-scale threats
that humanity faces today. Unlike nuclear risks or climate change, a
respiratory pandemic plays out on a timescale where coordinated
behavior change --- masks, ventilation, distancing --- can measurably
alter outcomes within weeks.
The main scientific result of this study is a
mechanistic forecast of a 42-fold reduction in deaths from modest coordinated action.
Yet, such coordinated action requires overcoming a wide range of cognitive traps,
some of which directly obscure a pandemic trajectory from inside a pandemic.
This study discusses some of these blind-spots under the label of "linear fooling"
to help find strategies for overcoming them.
The deeper message is that there currently exists no infrastructure for
explaining relevant mechanisms nor for deploying the
*gentle kind reasonable* coordination required to stop a pandemic.
Readers concerned with pandemic preparedness, global health infrastructure,
cross-disciplinary modeling, or the governance foundations needed for
coordinated species-scale work-logic cascades will find this paper's methods and
findings relevant.
.. was this (original AI proposal):
Pandemics are on the more tractable end of civilizational-scale threats
that humanity faces today. Unlike nuclear risk or climate change, a
respiratory pandemic plays out on a timescale where coordinated
behavior change --- masks, ventilation, distancing --- can measurably
alter outcomes within weeks. The scientific result of this paper is a
42-fold reduction in deaths from modest coordinated action; the
deeper message is that the infrastructure to deploy such coordination
does not currently exist, neither at national nor at global scales.
Moreover, certain cognitive traps
(such as linear fooling) which obscured the pandemic's trajectory are
the same traps that obscure other existential threats. Readers
concerned with pandemic preparedness, global health infrastructure,
cross-disciplinary modeling, or the governance foundations needed for
coordinated species-scale responses will find this paper's methods and
findings directly relevant.
**Abstract**
The COVID-19 pandemic demonstrated that humanity's ability to respond
to novel respiratory viruses remains dangerously inadequate.
This study extends the classical Susceptible-Infected-Removed (SIR) model
to include a *Germ Gap* --- that spatially and temporally separates
individual infectious particles ("Germs") from Infected individuals
and Susceptible hosts. The resulting SGIR framework enables more
principled predictions of extinctions of Germ populations in the Germ Gap.
To test this SGIR framework it was implemented in "PandemicSociety101",
a stochastic pure mass-action model with seven infection stages,
a simplified testing laboratory, hospital capacity monitoring,
and multiple pathways to death or recovery.
It was written for the Prototype Evolvix Compiler to facilitate
seamless switching between ordinary differential
equation systems (ODE, faster for huge populations) and the Stochastic Simulation Algorithm (SSA,
more accurate by respecting the indivisibility of individuals).
Using parameters calibrated in Spring 2020 to the US COVID-19 pandemic
(330 million population, 16 infections on 2020-02-14), this study simulates
an uncontrolled pandemic that infects approximately 289 million people and
kills approximately 13 million in Scenario 1 (without behavioral changes).
Scenario 2 starts with 1.5 million infections on 2020-05-17 but
can also assume a 50% reduction in probabilities for Actions
that both *Shed* and *Catch* the virus.
Such a modest reduction is achievable through coordinated use of
face masks, hygiene, and distancing.
Simulations show that despite the late start such organizing can stop this pandemic at
approximately 4.8 million total infections and 310,000 deaths.
This represents a 60-fold reduction in infections and a **42-fold reduction
in deaths** compared to uncontrolled spread.
This study also identifies a dangerous cognitive trap here called *linear fooling*.
In it limited testing capacity creates an illusion of pandemic control
precisely when infections are growing fastest.
These results suggest that non-pharmaceutical interventions, which increase the
Germ Gap can be remarkably effective without vaccines or herd immunity,
provided they are deployed with sufficient coordination across populations.
The mechanistically simple Germ Gap model -- if well-explained --
might play a key role in helping to persuade communities to voluntarily
improve pandemic resistance by measuring key parameters of the Germ Gap
in citizen science projects that cover the most relevant cases of use
in *gentle kind reasonable* ways.
To help continue improving pandemic resistance over the long term
may critically depend on open, well-organized, annual, global **Virodefense Olympics**.
Such games can encourage the *wide interdisciplinary diversity-encouraging* ("wid-e") research,
which is essential for finding *gentle kind reasonable* solutions
that increase the Germ Gap in the myriads of real-life scenarios that matter most.
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:depth: 3
:local:
1. Introduction
=================
The COVID-19 pandemic killed millions of people worldwide and exposed
fundamental weaknesses in how societies understand, monitor, and
respond to infectious disease outbreaks. While vaccines eventually
became available, the period before their deployment saw enormous
variation in outcomes across countries and regions, with
non-pharmaceutical interventions (NPIs) such as face masks, physical
distancing, and hygiene practices playing a critical but contested
role :cite:`Talic2021`. Major modeling efforts during the pandemic ---
including the Imperial College projections that drove UK lockdown policy
:cite:`Ferguson2020`, the SIDARTHE model for Italy :cite:`Giordano2020`, and
projections of post-pandemic transmission dynamics :cite:`Kissler2020` ---
demonstrated both the power and the limitations of mathematical modeling
for guiding pandemic response.
The classical Susceptible-Infected-Removed (SIR) model
(:cite:`KermackMcKendrick1927`) and its many extensions have been the workhorses of
mathematical epidemiology for nearly a century. These models typically
represent transmission as a direct interaction between Susceptible and
Infected individuals, parameterized by a transmission rate that
implicitly bundles together all the physical, biological, and
behavioral factors that determine whether infection occurs.
This implicit bundling, while mathematically convenient, obscures the
mechanistic chain through which respiratory viruses and all germs actually spread:
individual germs like virus particles are **shed** by an Infected person into the environment,
those viable particles must not **decay** for long enough to allow a
Susceptible person to **catch** them from that gap.
These three steps --- Shed, Decay, and Catch --- always play together
and can be independently influenced by human
behavior and technology. Face masks reduce both Shed and Catch rates.
Ventilation and UV sterilization increase Decay rates. Physical
distancing thereby becomes a randomly kind act of advancing local social cohesion
and global care by reducing the probability that a shed virus particle reaches a
susceptible person before decaying. In that abstract population sense it is mathematically
indistinguishable from vaccination, as both work by reducing the probability that
random particles infect Susceptible individuals.
This study proposes the SGIR model
(**S**\ usceptible - Germ **G**\ ap - **I**\ nfected - **R**\ emoved) as a
conceptual framework extension. It makes the **Germ Gap** explicit with mechanistic
chain that enables tracking Germs in the Gap that effectively separates
Infectious individuals and Susceptible individuals. The Germ Gap is not merely a
spatial distance; it is a composite measure that incorporates the
physical, temporal, and behavioral barriers that virus particles must
traverse to cause new infections. Increasing the Germ Gap is the
fundamental goal of all non-pharmaceutical pandemic defense.
Typical SIR models cannot help here, because they pretend mathematically
that there is no independent Gap; they are indistinguishable from models that assume
that infection can happen only in direct random meetings between Infectious and Susceptible individuals,
and that infection always happens at such meetings with a given probability.
The reframing in SGIR models has practical consequences:
* It redirects attention to **measuring the Germ Gap** experimentally.
* It focuses efforts on **increasing the Germ Gap** by equipping
populations with the expertise and tools to do so while aiming for success.
* It illuminates **causal mechanisms** that connect practical social-justice concerns to epidemiological
outcomes: crowding, poverty, and inadequate housing all *shrink*
the Germ Gap, mechanistically explaining why disadvantaged
populations bear disproportionate pandemic burdens
(:cite:`Caplan2020`, :cite:`Mosley2025`).
The same mechanism works in reverse. Investments in living space,
ventilation, and workplace safety *increase* the Germ Gap and so
reduce transmission across the whole population, not only the
worst-off.
In such cases disease protection emerges as a structural side effect of certain forms of
equitable development --- which makes such investments in humane equal
dignity considerably more self-serving than they may seem at first glance.
Such investments may shrink some short-term bottom lines, but over the long term pandemic-grade investments
in social cohesion are priceless. They build
stability that cannot be bought "on demand" once a pandemic is
already slow-motion exploding.
When the Germ Gap gets compromised, the pandemic burden
often hits those harder who do much essential work for upholding a society.
For example, the demographic composition of the
U.S. health workforce :cite:`NCHWA2014`, read alongside
:cite:`GouldWilson2020` and :cite:`Wurth2020`, shows how systemic
racism and economic inequality act as *preexisting conditions* that
mechanistically shrink the Germ Gap for African Americans
and many other marginalized communities. Yet, where such minorities
are essential for health care, systemic inequalities that hit them
hard can spiral into much broader problems. Face masks are easy to
produce over the short term, better housing can be built over the mid term,
but raising, training, supporting, and retaining a generation of good nurses is a much more
long-term undertaking that requires corresponding long-term planning.
How useful are visions of "a thousand Einsteins and a thousand Mozarts"
born in future off-world colonies :cite:`Bezos2019Einsteins`, if most of
present would-be Einsteins on Earth lack the basics they need to develop their gift?
More pointedly, if economic pressure forecloses vocations of sustained research,
then how is that different from forcing the Einsteins of this world
to accept indirectly forced labor if they wish to avoid starvation?
The pattern is global and plays out by default unless enough leaders and
institutions can be persuaded to walk the narrow path
towards developing the mental wealth of all the people in all the nations
:cite:`Beddington2008MentalWealth`. This study presumes that winning against pandemics
is impossible without such a broad development of mental wealth for all.
This is not a quick fix. There is no broad and easy path to the
*gentle kind reasonable* solutions that less powerful countries need to
support their not-yet Einsteins (e.g. see :cite:`Wintour2020`).
Network effects are complicated;
even powerful people cannot forever escape the network effects of their
actions on the less fortunate. For example, :cite:`Wilde2018`
reports how Stalin's purge of his own physicians left him without
competent care when his fatal stroke came --- short-term cruelty
toward a constructed "out-group" boomeranging on an
unwitting perpetrator.
The pattern is not new: :cite:`JohnOfEphesus2017Pearse` reports how during the Justinianic
plague (542 C.E.) the poor died first and how some saw this as
the better fate because of the horrors that followed.
It is striking to see the SGIR Germ Gap mechanism reverberate across centuries.
Yet, a narrow path to beating complicated network effects does not imply that
it cannot be found. Once found and defined, it can be explained and taught.
Hence, the importance of mental wealth for life-giving decision-making.
Why does the same dynamic keep repeating?
:cite:`Hare2017` and :cite:`HareWoods2020` propose that
humans succeeded as a species through selection for
prosociality --- the human talent that enables coordinated cooperation by trusting others.
Stopping a pandemic in mid-flight may therefore depend on
something much deeper than face masks, vaccines, and short-term administrative decisions.
This study is built on the working premise that stopping pandemics
requires mental wealth and the will to construct reliable work-logic cascades
for trusting others in order to extend genuine cooperation.
This trust-based cooperation is essential for
*gentle kind reasonably* increasing pivotal Germ Gaps
through life-giving decision-making for the common good of *everyone*.
Further analyses in other papers of the Matheo series
(see `Balospe.com `__) show that such work ultimately
forces a stark value decision, because maximizing infinitely divisible dividends
structurally conflicts with best supporting the intrinsic value of indivisible individuals.
One of these ultimate priorities must take the lead in how
countless conflicts of interests are resolved in a complex world.
This study presumes that
humane equal dignity is best guarded by respecting the intrinsic value of
unique and indivisible individuals and that this value is worth guarding even if at the cost of
compromising the maximizing of bottom lines of infinitely divisible dividends.
These abstractions matter, because pandemics cannot exist without infecting indivisible individuals
and to do so individual germs must cross infinitely divisible Germ Gaps
between individuals. Increasing Germ Gaps can stop pandemics as shown below,
but doing so cannot succeed at scale without investing divisible resources accordingly.
How to best increase Germ Gaps without overcomplicating requires myriads of more detailed
models of the SGIR type. To best guard individuals from infections without overreaching,
the studies that build such models must invest their resources accordingly.
This study does not aim to construct any specifically applicable SGIR model
with all the operational details needed for deployment in any particular demographic.
The aim here is more basic.
The goal of this study is to introduce the conceptual framework required
for building SGIR models through an example that tests its usefulness for a very simple question:
Does there exist any biologically reasonable scenario in which the SGIR framework
points to realistic changes in Shed, Decay, or Catch rates capable of
stopping a COVID-19-sized pandemic without a vaccine?
To this end the SGIR framework is implemented
in a model here called "PandemicSociety101".
This model tracks counts of individuals through seven stages of infection and includes a
simplified testing laboratory and hospital system.
Its code is formulated for the high-precision computational workers of the Prototype Evolvix modeling language
:cite:`PrototypeEvolvixCompiler`, which supports both
deterministic (ODE) and stochastic (SSA) simulation modes to facilitate forecasting
time courses of how many individuals of the modeled types exist.
Analyzing the deep stack of mathematical models thereby constructed amounts to
a constructive existence proof that indeed there exist at least some
biologically reasonable scenarios in which a pandemic can be stopped in mid-flight
without vaccines, simply by using imperfect face masks at sufficiently large scales.
This report is organized as follows. The next section (2) describes the basic SGIR concept, its underpinning
pure mass-action implementation, and the concrete PandemicSociety101 model built on these,
before detailing scenarios and parameters derived in Spring 2020 from observing the
unfolding Coronavirus pandemic. The Results (3) describe how an uncontrolled pandemic
can unfold in this model and how a simple calculation can be used as an effective early
warning system. Then simple non-pharmaceutical interventions (NPIs) are described that
can avert the brunt of a pandemic even after it started, albeit only
if a certain population-wide mobilization can be achieved. Since such a mobilization
critically depends on clearly communicating critical information on the state
of the pandemic, various non-trivial cognitive traps are discussed that emerge
for all who try to observe an unfolding pandemic from inside of that pandemic.
The final Discussion (4) summarizes advantages and limitations of SGIR models
as actionable frameworks and points to the pivotal importance of a sufficiently
well-organized coordination infrastructure for non-pharmaceutical virodefense.
The possibility of organizing annual global "Virodefense Olympics" to keep
improving pandemic defenses is raised before concluding that working through the
implications of the SGIR model offers meaningful contributions to both, the post-processing
of what happened during the Coronavirus pandemic, as well as the preparation
for helping to reduce the risks for the next pandemic.
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2. Model Description
======================
2.1 The SGIR Framework for modeling Germ Gaps
------------------------------------------------------
The classical SIR model tracks three types of individuals: Susceptible (S),
Infected (I), and Removed (R). Transmission occurs when S and I
individuals interact, at a rate proportional to the product S * I. That rate is
defined as the much discussed quantity R\ :sub:`0`, which offers the following simple intuition:
If R\ :sub:`0` > 1 an epidemic will be growing (presumably to infect the whole
population unless herd-immunity gets in the way); otherwise it will die out locally.
This simplicity is in contrast to the exceeding difficulties in dissecting mechanistically
what R\ :sub:`0` might be in any specific context (beyond deriving it operationally
like a black box parameter estimated from observed doubling times).
The SGIR model introduces two new conceptual types of individuality that combine
to form the **Germ Gap** --- *Germ* (the individual infectious particles inside) and *Gap*
(the finite physical environment that holds them) --- with **G** in SGIR standing
for that **Germ Gap**.
Thereby SGIR models offer a mechanistic way to help to disentangle the
mathematical conglomerate parameter R\ :sub:`0`, which describes all
necessary and sufficient steps of transmission with a single number.
The **Germ Gap** represents the physical environment through which virus particles
("Germs") must travel between an infected source individual and a susceptible
target individual.
(In this paper *Germ Gap* names the technical concept; figures may retain the
equivalent label *Gap of Germs*; see Section 4.1 for the naming rationale.)
The transmission chain then becomes:
| **Infected** --- *(Shed)* --->
| **Gap** --- *(survive Decay)* --->
| **Germs** --- *Catch* ---> **Susceptible turns Infected**
Each step has its own rate to help track the amount of individual germs:
- **Shed rate:** How many Germ particles an infected individual releases
per unit time. This depends on infection stage (asymptomatic
individuals may shed less or more than symptomatic ones), respiratory
activity (e.g. singing sheds more than breathing), and protective measures
(e.g. masks reduce shedding).
- **Decay rate:** How quickly Germ particles become non-infectious in
the environment. This depends on environmental conditions
(e.g. temperature, humidity, UV exposure), surface properties, and active
decontamination measures.
- **Catch rate:** The probability that a susceptible individual encounters
and is infected by surviving Germ particles. This depends on factors like
proximity, ventilation, protective equipment (e.g. masks), and individual
immune factors.
The effective Germ Gap can be seen as a complex composite of these
three rates in a given context: when Shed or Catch rates decrease, the Germ Gap increases
and transmission slows (but when Germ Decay decreases, the Germ Gap decreases).
The key insight is that small respective improvements in each
of the three rates can strongly compound, potentially achieving even more than multiplicative
overall reductions in transmission without requiring single
interventions to be perfect in order to be overall effective.
Thus, it is possible in principle to push a potential pandemic
that has a R\ :sub:`0` > 1 for one given set of behaviors in a population
to become R\ :sub:`0` < 1 once a suitable different set of behaviors is adopted.
As the simulation results presented below show, this transformation can apparently
even be achieved after a pandemic is well underway, as long as it has not yet
run its course.
2.2 PandemicSociety101: the First SGIR Implementation
-----------------------------------------------------------------
To test the value of the SGIR framework under biologically realistic circumstances,
a model of the Coronavirus pandemic was constructed in in Spring 2020.
Called PandemicSociety101, it was motivated by the "fool's hope" of obtaining
some modeling insights that might help stop the then emerging
slow-motion explosion of Coronaviruses and the COVID-19-induced suffering it caused.
Figure 1 provides an overview of the complete
PandemicSociety101 model architecture, showing all compartments,
transitions, rate parameters, and the connections between infection
stages, the testing laboratory, hospital system, and recovery/death
pathways. The model's input scenarios (Scenario 1: Feb 2020,
Scenario 2: May 2020) and their parameter configurations are also
indicated. For details, see Prototype Evolvix source code (see Supplementary Info).
.. _b19-form-sgir-mmv5-fig01-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig01-model-overview.*
:alt: Figure 1 -- Core model of PandemicSociety101
:width: 90%
:align: center
**Fig.1:** Core model of PandemicSociety101
(:ref:`full size ` |
:ref:`list ` |
`download `__).
**Infection stages.** The model tracks individuals through seven
infection stages following initial virus contact:
.. list-table:: **Table 1:** Stages from Infection to Death
:header-rows: 1
:widths: 25 15 60
* - Stage
- Duration
- Description
* - Starts0grow
- 1 day
- Virus growth initiated; not yet infectious
* - Infect1Hide
- 2 days
- Infectious, high shed, no symptoms, hidden status
* - Infect2Anti
- 3 days
- Infectious, high shed, hidden, antibody-positive
* - Infect3Mild
- 2 weeks
- Infectious, symptomatic; most individuals recover here
* - Infect4StrongHOS
- 2 weeks
- Strong symptoms, requires hospital bed
* - Infect5CritclBED
- 2 weeks
- Critical symptoms, needs hospital bed or dies
* - Infect6DeadlyICU
- 2 weeks
- Needs ICU or dies
* - Infect7ExpectICU
- 2 weeks
- Expected death; beyond ICU capacity to save
PandemicSociety101 implements the SGIR concept as a pure mass-action
stochastic model for the Prototype Evolvix Compiler modeling language, variant MMs0r3p1
:cite:`PrototypeEvolvixCompiler`. The Prototype Evolvix compiler transforms the model for
the Sorting Direct Method for stochastic
simulation (:cite:`McCollum2006` as implemented by :cite:`Ehlert2014`; more accurate for smaller
populations but slow for large ones) or
the Sundials IDAS solver for corresponding deterministic ODE integration (:cite:`hindmarsh2005sundials`;
faster for large populations at the cost of hallucinating effects of broken-up parts of individuals).
All rates are specified in units of 1/day and compartments are always sized such
that absolute amounts (counts) of individuals are simulated and never concentrations,
in order to ensure a rigorous understanding of all individualities involved.
Individuals progress through the stages defined above and exit the pandemic as
either Recovered (outside or in hospital) or Dead (pre-hospital
or in hospital). Recovered individuals are assumed immune and cannot
be reinfected within the simulation timeframe.
To simplify the model, overall population size changes during the time of the pandemic
are assumed to be negligible (i.e. no births and no independent deaths of individuals).
**Virus tracking via ASHA.** The environmental virus load (the "Gap")
is tracked using the ASHA (Aggregated State Homogeneity Approximator)
framework used here for the first time. It maintains density-dependent dynamics by tracking the
number of environmental "places" that are either contaminated ("With")
or clean ("Lack") out of a fixed total ("Aces"). This provides proper
density-dependent saturation --- the environment has a finite capacity
for virus, preventing exponential accumulation, which cannot happen in reality.
The idea for ASHA grew from the need to be able to tune more parameters
of population models than usually exposed in oversimplified models.
Examples demonstrate the profound loss
of understanding that can result from oversimplified models that pack
too much biology into a composite parameter (such as carrying capacity K, :cite:`Mallet2012`).
The ASHA framework is built on respective concepts (see :cite:`Mallet2012`),
as illustrated and extended in Figure 2 and 3 (see figure captions at the end and Prototype Evolvix
source code for more details.).
.. _b19-form-sgir-mmv5-fig02-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig02-evolvix-actions.*
:alt: Figure 2 -- Evolvix Actions
:width: 90%
:align: center
**Fig.2:** Evolvix Actions
(:ref:`full size ` |
:ref:`list ` |
`download `__).
Figure 2 shows how Evolvix
**Actions** define the elementary events that move time forward in the model.
If the required individual Parts exist, the assumption of random mixing dictates that
they will eventually meet randomly. When they do, the respective Action may happen
with a certain defined rate per time. If the Action happens,
all required Parts instantly disappear to produce new Parts, the products of that Action.
The specified Rates for an Action are all multiplied together to
define its propensity to happen next. In a stochastic system, where the
individuality of Parts cannot be divided up, a Stochastic Simulation Algorithm
(like the Sorting Direct Method :cite:`McCollum2006,Ehlert2014`) calculates the propensities of all actions and then
rolls the dice to find the next Action and when it will occur. Then time is moved
forward, the changes defined by that Action are then implemented by changing the respective
Amounts of all Parts involved in that Action. Finally propensities are recomputed for the next Action.
This flexibility in the timing of Actions allows for the indivisibility of individual Parts
to be preserved. This contrasts with deterministic simulations, where
the time-steps forward are assumed to be primary and the Amounts of Parts are
instead treated as infinitely divisible. This can lead to fundamentally different
biological outcomes, because "deterministic" populations with only "half an individual" are either extinct in reality or not.
See :cite:`Ehlert2014` and the one-page overview in :cite:`PrototypeEvolvixCompiler`
for an introduction to how these approaches contrast.
This formalism is equivalent to the standard mass-action kinetics formalism,
albeit implemented with extra care to ensure that the individuality of individual Parts
is always respected when simulated stochastically. Moreover, a declarative syntax is
used that was designed to make elementary biological Actions easier to check in bottom-up modeling
(in contrast to differential equations, which always assume a system-wide overview).
Figure 3 shows how **ASHAs**
extend this rigorous mass-action kinetics by assigning unit-sized Places to unit-sized
individuals in a population, tracking how many Places ("*Aces*") are *With* or are *Lack*\ing a
given individual (e.g., a virus contamination), out of a fixed total number
of *Aces*. This provides ten variables to define an ASHA state (Aces, Dice,
With, Lack, InIt, OuOf, Gain, Loss, Grow, Fade) that controls
density-dependent dynamics by defining explicit population biological functions.
Such an explicit approach to biouncertainty is preferred here to
the implicit bundling of uncertainty into summary parameters (like carrying capacity K,
see :cite:`Mallet2012`), because the resulting clarity may open up new avenues for measuring
important quantities or at least help clarify critical biological
distinctions. The full ASHA specification is in the Supplementary
Prototype Evolvix model code; Figures 2 and 3 provide a visual guide for reading
that code.
Actions in this model (as shown in :ref:`Fig.2 `)
also formally interact with two special abstract ASHAs called "StopHarm" and "CallHelp".
These parts of the code exist to help model the effects of scaling up population-wide
work-logic cascades in case such cascades are constructed while the pandemic is still active.
The Discussion points to a related study from 2020 that argues why
it is feasible to scale up such work-logic cascades to help coordinate pandemic defenses.
For the purposes of this study here
all these work-logic cascades in the code are effectively deactivated by setting all
respective parameters to 1, which means that they do not bias any Actions
in this model in any way. The purpose of this study here was to determine,
whether it is possible in principle - given a 100% adoption rate of an imperfect measure -
to substantially slow a pandemic *after* it has long left its stochastic stage.
If this cannot be demonstrated in principle for at least one biologically realistic
parameter combination, then one might argue that there is little point in trying.
In that case, without vaccines, the much debated herd-immunity does indeed become
the only remaining dim hope for slowing a pandemic.
However, as shown below, parameter combinations do exist that inspire the hope
that it is indeed possible to stop an unfolding pandemic in mid-flight.
.. _b19-form-sgir-mmv5-fig03-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig03-asha-places.*
:alt: Figure 3 -- ASHA Places Model
:width: 80%
:align: center
**Fig.3:** ASHA Places Model
(:ref:`full size ` |
:ref:`list ` |
`download `__).
In the PandemicSociety101 model virus particles are classified as either **Fragile** (decaying
quickly, e.g., airborne droplets) or **Durable** (persisting longer,
e.g., surface contamination). Each is tracked by its own ASHA instance.
Each infected individual in each infection stage contributes to viral
shedding at stage-specific rates.
**Simplified testing laboratory.** The model includes a simplified
testing pathway where 100% of individuals are tested at entry into
Infect1Hide and Infect3Mild stages. This design is deliberately
simplified to explore the phenomenon of *linear fooling* (see Results)
rather than to model realistic testing capacity.
**Hospital system.** Individuals reaching Infect4StrongHOS and beyond
are all assumed to receive hospital care. Hospitals are assumed to be
as large and as available as they need to be in order to take good
care of all patients in the respective stages. The model tracks hospital and
ICU occupancy under these idealized conditions and
distinguishes between deaths occurring before
hospital admission and deaths in hospital.
2.3 Scenarios and Parameters
-------------------------------
**Scenario 1 (Uncontrolled, 2020-02-14):** 16 infected individuals in
a population of 330 million (US). No behavioral change, no
interventions. Virus transmission parameters reflect baseline
SARS-CoV-2 characteristics. This scenario was calibrated to the observed
US doubling time of approximately 3.25 days in the early phase in 2020.
The resulting model parameters lead to an emergent doubling time of about 4.8 days
as measured from the simulated model output.
**Scenario 2 (Face-masking, 2020-05-17):** Starting from 1.5 million
infections (ca. 90,000 deaths) in a population of 330 million, with three sub-options:
- **Option A:** No change in Shed, Decay, or Catch rates (baseline).
Then the pandemic continues as in Scenario 1.
- **Option B:** 50% reduction in *either* the probability of virus
Shed *or* Catch rate. This represents partial facemasking
(or equivalent NPI adoption).
- **Option C:** 50% reduction in *both* Shed probability *and* Catch
probability simultaneously. This represents fully coordinated facemask
adoption at the defined level of efficiency (or equivalent NPI
adoption by other means).
The full model specification, including all parameter values and ASHA
configurations, is available as Supplementary Material (Prototype Evolvix source
code, ~3,900 lines; need a 4K monitor for efficient reading).
To generate the raw results for the figures shown,
the corresponding parameter combinations in that file need to be
switched on or off, respectively. All computing work, results analyses,
and figure compositions were completed by Loewe by mid 2020.
.. raw:: html
.. raw:: latex
\newpage
3. Results
============
3.1 Scenario 1: Anatomy of an Uncontrolled Pandemic
-------------------------------------------------------
Without interventions, the PandemicSociety101 model simulates a
pandemic that infects approximately 289 million people of the
330 million in the US population modeled. Of these 13.8 million individuals die.
Three stochastic simulation replicates closely track the
deterministic prediction made by ordinary differential equations (:ref:`Fig.4 `).
This confirmes that for a randomly mixing population of 330 million, stochastic effects
are minimal when starting with 16 individuals. The only time when such
stochastic effects are even observable is
during the earliest phase when infection counts are small enough for
chance effects to slightly delay or accelerate further spreading.
.. _b19-form-sgir-mmv5-fig04-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig04-scenario1-deaths.*
:alt: Figure 4 -- Pandemic deaths in default Scenario 1 on linear and on log scales
:width: 70%
:align: center
**Fig.4:** Pandemic deaths in default Scenario 1 on linear and on log scales
(:ref:`full size ` |
:ref:`list ` |
`download `__).
Fig.4A shows the pandemic growth on a linear scale, which is only helpful
during the later stages of a pandemic. Since pandemics are mostly driven by
multiplicative growth, Fig.4B shows the same simulation results on a log scale,
which is more informative during the early stages of multiplicative growth.
**Communicating clear and present danger from slow-motion explosions.**
Much thought was given to how the tricky multiplicative dynamics of pandemics might be
translated into clearer language for people who are not used to dealing with the underpinning mathematics.
A simple analysis of general audience pragmatics and semiotics of the respective
mathematical language revealed a major barrier to all who wish to use its standard terminology
to communicate the urgency of pandemic actions. The keywords to translate here are
"exponential growth". Both words seem to make sense to most people. Unfortunately they
map intuitively to the wrong notions in the unreflected use of most people.
"Growth" is a good thing most of the time
in the mind of most people, and "exponential" maps to "a lot". Thus,
"exponential growth" points intuitively to "a lot of a good thing" for most people,
unless they think through the context, which tells them that fast growth of a
dangerous virus is *not* a good thing.
To find a way around this problem, the term "slow-motion explosion" was
defined for describing the growth of a pandemic. It maps to the same
underpinning chain-reaction that drives any explosive growth from nuclear
chain reactions to pandemic transmission growth. All these are
mathematically describable by exponential functions.
Including "slow-motion" highlights the fact that pandemic times of response to changes in behavior are
closer to response times of steering a container-ship than a race car.
Ending with "explosion" highlights the fact that the impact of the respective
shockwave will come nevertheless and is in principle contained by the space in which it happens.
That this space is usually best described in multiplicative terms
is only one of several unusual aspect of how pandemics work.
.. _b19-form-sgir-mmv5-fig05-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig05-scenario1-logplot.*
:alt: Figure 5 -- Log-plot overview of uncontrolled Pandemic Scenario 1
:width: 90%
:align: center
**Fig.5:** Log-plot overview of uncontrolled Pandemic Scenario 1
(:ref:`full size ` |
:ref:`list ` |
`download `__).
To underscore the multiplicative nature of pandemic slow-motion explosions,
it is generally useful to show how they unfold on a log-scale.
Hence, many figures here are shown on a log-scale. The linear scale tends to
be most useful for the last few moments before a slow-motion explosion crashes
into its hard limiting space factor (e.g. it is impossible to infect more individuals
than exist in a given population).
:ref:`Fig.5 ` shows an overview of several interesting quantities
for tracking slow-motion explosions on a log-scale
in the PandemicSociety101 model without interventions.
In this model the pandemic infects approximately 289 million people (88% of the
330 million population) and kills approximately 13.8 million (4.2%
overall; 5.4 million pre-hospital, with 23.6 million (7.2%) healing
in hospitals and 252 million (76%) recovering from mild forms outside
hospitals). Approximately 40.8 million (12%) are spared infection
entirely.
In :ref:`Fig.5 ` one may think of the virus load as
an unexpected "iceberg" emerging from the deep, which
drives infection rates upward while remaining invisible on
linear scales for most of the time - and hence on collision course with the ship of
the civilization it attacks.
A careful comparison to :ref:`Fig.4 `
shows that in week 1 to week 14 **on a linear scale, the
virus seems to do "almost nothing" during the period when in reality it is most
active**. In that time it establishes the ultimate size of the slow-motion explosion it causes.
By the time infections become visible on a linear
plot, the "exponential growth" phase is nearly complete and the size and punch
of the slow-motion explosion have been almost completely determined.
This linear-vs-logarithmic perception gap is a fundamental barrier to broader
public understanding of pandemic dynamics. While it is easy to
explain in principle, there is such a long list of detailed
implications and complications that even experts get easily tripped up (as other Results
in this study show).
3.2 The HalfMax method as an early warning system for pandemics
----------------------------------------------------------------
**How even experienced modelers can be fooled.** :ref:`Fig.6 `
illustrates a sobering point about the deceptive nature of
exponential growth on linear scales. This figure, from Loewe's
earlier work on stochastic simulation algorithms (Fig.7a in :cite:`Ehlert2014`), shows 100 stochastic simulations of a simple
unbounded exponential growth model starting with 10 individuals.
.. _b19-form-sgir-mmv5-fig06-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig06-exponential-fooling.*
:alt: Figure 6 -- Slow-motion explosions are easy to miss
:width: 40%
:align: center
**Fig.6:** Slow-motion explosions are easy to miss
(:ref:`full size ` |
:ref:`list ` |
`download `__).
On a linear scale the resulting slow-motion explosion shows the characteristic "hockey stick" pattern:
the population appears invisible for a long time, then suddenly
explodes.
These simulations were produced in 2014, years before COVID-19.
Loewe had extensive experience with interpreting systems that are
much better understood on multiplicative log-scales --- he was eventually even
exploring how a multiplicative ("non-Newtonian") calculus, in which products
and ratios take the structural role of sums and differences
(:cite:`Grossman1972`, :cite:`Grossman1983`), might offer a more natural language
for such growth in Evolvix.
Yet when
he read US reports of 16 Coronavirus infections on 2020-02-15 --- a number
strikingly close to the 10 individuals that reliably triggered
well-defined exponential growth in his 2014 simulations shown in :ref:`Fig.6 `
--- even Loewe failed to realize
the significance of that alarming information.
What chances do others have who live much more in the linear world
If even a researcher whose professional work centered on exactly
these multiplicative dynamics can be fooled by linear scales
that make deterministic slow-motion explosions look like "nothing is happening".
This personal experience underscores the systemic
nature of linear fooling: it is not a failure of knowledge but a
failure of perception ("realizing") that affects everyone, including even some experts who
should theoretically and practically know better.
**HalfMax method.** It is pivotal to mitigate this perception problem in order to
increase the reaction time remaining for behavior modification before the brunt of a pandemic hits.
Like other early warning systems for natural disasters,
such as tsunamis and tornados, there is no exact way to predict the precise
amount of damage that will result from doing *nothing*. Except it is clear that
maximal damage will result from not seeking shelter, which is equivalent to
no behavioral modification when a pandemic hits. Yet, even though pandemics
move slower than tsunamis or tornados, time is of the essence.
To communicate that urgency it is essential to have a **reliable early-warning system**
for calculating how much time might still remain if the current behavior
and the current germs were to continue without notable changes.
To this end Loewe developed the HalfMax-method, a quick rule-of-thumb method
that only needs a pocket calculator for helping
a broader audience without access to
sophisticated simulation models to quickly translate a reported
doubling time *T* :sub:`Doubling` into an expected waiting time before
the brunt of a pandemic will hit *T* :sub:`HalfMax` --- if nothing changes, i.e. all rates stay as they are
and a random mixing population without changes in behavior can be assumed.
The HalfMax method is not about precision; it's about triaging whether
an emergency response is needed and how much time may remain to organize it.
The HalfMax-method builds on the basic understanding that all pandemics are slow-motion explosions
that follow the logistic growth curve, which predicts that absolute growth will be
fastest at half of the maximal capacity, before it starts to slow down again.
This allows for a simple doubling-time arithmetic to estimate the
HalfMax point when at most 50% of the population will be infected and hence
infection rates will be highest before they naturally slow down as susceptible
individuals get increasingly rare.
The point in having such a simple "pandemic count-down" timer at hand
is in distributing as best possible the work required to increase Germ Gaps
such that the overall size of the pandemic can be reduced before it is too late.
Interventions after the HalfMax point will have significantly less impact
and their effectiveness may be difficult to distinguish from an expected natural decline
in infection numbers.
Like with tsunami-warnings, if everyone can predict the worst based on observed data, everyone can help to reduce the impact.
It only takes a pocket calculator to compute T :sub:`HalfMax` a HalfMax waiting-time forecast.
Therefore the HalfMax-method is easily implementable and checkable where it matters most:
at places of decision, where behavioral recommendations are made that affect the Germ Gap.
If a rational explanation is given and people can check it,
a given mitigation strategy is much more likely to succeed, even if it requires some sacrifices in comfort.
As the value is not in a precise point estimate, a min-max range should always be given.
The greatest value of the HalfMax method is in the 'street-wise math' that helps
to reduce the 'blind faith' that many felt was required of them in
understanding the threat from the Coronavirus pandemic.
The HalfMax core equation is this:
*T* :sub:`HalfMax` ≈ *T* :sub:`Doubling` × log :sub:`2` ( *N* :sub:`HalfMax` / *N* :sub:`NowInfected` ) [Eq.1],
where *N* :sub:`HalfMax` is half the number of all susceptible individuals (~165 million in the US) and
*N* :sub:`NowInfected` approximates how many have already been infected by now.
The purpose is to quickly translate a key observable (like a 5-day doubling time)
into actionable intelligence offered by a rough early-warning forecast.
That is why it can be thought of as a pandemic equivalent for a tsunami early-warning system.
.. _b19-form-sgir-mmv5-fig07-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig07-halfmax-forecast.*
:alt: Figure 7 -- HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast
:width: 80%
:align: center
**Fig.7:** HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast
**Fig.7:** HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast
(:ref:`full size ` |
:ref:`list ` |
`download `__).
Applying the HalfMax forecast to his own situation in 2020, Loewe calculated the following rough numbers
as reported in :ref:`Fig.7 `:
*T* :sub:`HalfMax` ≈ 32 - 75 days ≈ 3-7 days × log2 ( 165 mio / 0.1 mio ) [Eq.2],
using a point estimate of *T* :sub:`Doubling` ≈ 5 days
to forecast *T* :sub:`HalfMax` ≈ 53 days after 2020-03-27, the day Loewe started to
take his first serious look at the Coronavirus pandemic (with 101,657 reported infections).
The shock of realizing what this graph meant moved Loewe's research trajectory
to set aside his other career plans in order to explore how such existential threats
might be mitigated. Without understanding Fig.7, Loewe would have never completed
the PandemicSociety101 model, even though, arguably, he had accumulated all essential
insights for completing such an SGIR model by about ≈ 2016-2018.
Naturally, these HalfMax forecasts assume continued random mixing with no changes in behavior whatsoever.
Yet, as well known, drastic changes in behavior are to be expected and did occur.
To examine the usefulness of the HalfMax method given such changes,
its forecasts were compared to actual CDC data through May 2020 (:ref:`Fig.8 `).
.. _b19-form-sgir-mmv5-fig08-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig08-cdc-data-clocks.*
:alt: Figure 8 -- Testing the HalfMax early-warning method in a real pandemic
:width: 80%
:align: center
**Fig.8:** Testing the HalfMax early-warning method in a real pandemic
(:ref:`full size ` |
:ref:`list ` |
`download `__).
:ref:`Fig.8 ` shows that the observed trajectory is predicted in useful ways
between bounds that repeatedly reset the HalfMax clock to account for
observed changes in behavior that affects the Germ Gap.
These predictions suggest that the HalfMax method can be harnessed to help
not only to "flatten the curve", but even to "end the curve" if
sufficiently effective non-pharmaceutical interventions can be found in time.
The black-box nature of R\ :sub:`0` in typical SIR models offers little hope for such
interventions. However, the mechanistic breakdown of R\ :sub:`0` that is offered by
SGIR models opens principled avenues for fighting pandemics by reducing the
respective Shed and Catch rates (e.g. via facemasking) as well as increasing Decay rates
for viruses (e.g. via air-filters and surface cleaning).
Thus, SGIR modeling might offer a sliver of hope, if only a "fool's hope"
in a dark time.
3.3 Scenario 2: Stopping a Pandemic with Face-masks
----------------------------------------------------
The maybe most startling result of this study is shown in :ref:`Fig.9 `,
where 3 pandemic forecasts are compared, all starting
from 1.5 million infections on 2020-05-17 , each simulating different behaviors
after 90,000 deaths had already occurred.
The two NPI options simulated are best compared to two different
types of use of face-masks, both of which produce dramatically different outcomes,
especially when combined. Table 2 compares the outcomes, assuming that only 50% of
all infectious particles are filtered. Measurements of face-masks
suggest better filter efficiency (e.g. 74% to 90% measured :cite:`Asadi2020`),
so the parameters chosen here appear workable in practice.
.. _b19-form-sgir-mmv5-fig09-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig09-how-to-stop-a-pandemic.*
:alt: Figure 9 -- Scenario 2C stops a pandemic in mid-flight with face masks
:width: 90%
:align: center
**Fig.9:** Scenario 2C stops a pandemic in mid-flight with face masks
(:ref:`full size ` |
:ref:`list ` |
`download `__).
.. list-table:: **Table 2:** Scenario 2 for how to stop a pandemic without vaccines.
:header-rows: 1
:widths: 15 25 25 35
* - Option
- Total Infections
- Total Deaths
- Face-mask adoption effects
* - A
- ~289 million
- ~13 million
- No face-masks (baseline)
* - B
- 57--63 million
- 2.1--2.3 million
- 50% reduction in EITHER Shed OR Catch rates
* - C
- **~4.8 million**
- **~310,000**
- 50% reduction in BOTH Shed AND Catch rates
The progression from A to B to C demonstrates the more than multiplicative
compounding effect of combining interventions. A single 50% reduction in Shed OR Catch rates
(Option B) achieves a 4.6--5.1-fold reduction in infections. Combining
both 50% reductions (Option C) achieves a **60-fold reduction** in infections ---
far more than any simple intuition would predict from doubling the interventions.
These strong compounding effects are the quantitative foundation for the success of
Germ Gap based interventions. The explicit modeling of
density-dependent effects due to the Germ Gap as tracked by the ASHA framework
predicts an even stronger compounding than simple multiplicative effects (2x2 = ~4-fold
or 4.6x5.1 = ~23-fold).
These Germ Gap effects are the reason for why even without any intervention the pandemic in this SGIR model
does not approximate 100% infection: eventually the probability of
getting enough viruses across the Germ Gap becomes so low that the remaining Susceptibles
can no longer be reached. The non-pharmaceutical interventions
that increase the Germ Gap as reported in Table 2 simply lower that
probability enough, such that the pandemic "simply goes away" as famously claimed.
These results are consistent with independent modeling :cite:`Stutt2020`,
showing that facemasks combined
with lockdown measures can effectively manage the pandemic when
adopted broadly. The SGIR framework provides a detailed mechanistic
explanation for *why* such combinations are so effective:
the details are in a probabilistic game of dice, played out in real-life in the Germ Gap.
This appears to be a case
where independently working together is greatly rewarded by the
mathematics underpinning the reality of pandemics: those who
wear a mask while infected reduce their Shed-rate for the benefit of everyone.
At the same time, those who also wear a mask despite not being infected,
will reduce their Catch-rate. When both work together, their combined reward in
safety gets a mathematical extra-safety bonus, simply for working together.
Hence, despite reducing the *product* of
Shed and Catch probabilities only by four when cutting both probabilities
by half, the overall effect is amplified into the observed 60-fold overall reduction
by the density-dependent effects tracked by the ASHA framework.
Seeing this Figure 9 by mid 2020, Loewe concluded that his "fool's hope" would not be a real hope if
it was impossible to show for biologically reasonable parameter
combinations that there exists a realistic road to success such as in Scenario 2C.
This insight, however, fundamentally transforms the battle in fighting a pandemic
from the proximal cause ("fight germs") to a more distal cause ("return *gentle kind reasonably* to reality").
Thus, if three apparently realistic manipulations of
probabilities for shedding, decaying, or catching the virus can actually stop the pandemic,
then a pandemic becomes a battle-cry of reality for improving *gentle kind reasonable* engaging
in order to invite everyone to *gentle kind reasonably* returning to reality.
Note, how all three properties of this life-trifecta are essential for success;
yet explaining how it works in detail, what happened to that fool's hope, why it existed in the first place,
and how to best learn from it all are topics beyond the scope of this study
and require in-depth analyses of many other topics (see the Matheo study series and
the broader work at Balospe.com).
While the remainder of this study analyzes a few general observations of interest to
pandemic experts, Loewe's 2020 work on meta-pandemic topics related to
fighting pandemics by improving *gentle kind reasonablness* is to be discussed
in his forthcoming Matheo-b20 study (to be published at Balospe.com/en/study once sufficiently complete).
3.4 Linear Fooling: A Dangerous Cognitive Trap
--------------------------------------------------
The model's simplified testing laboratory reveals a phenomenon that may be called
*linear fooling* (:ref:`Fig.10 `). When testing capacity is limited to a
fixed number of tests per day, and under the (big) assumption
that all symptomatic individuals get tested, the following sequence will occur:
1. **Early phase:** Testing capacity exceeds demand. All infections
are detected. Statistics appear reliable.
2. **Transition:** Infections grow exponentially and eventually exceed
testing capacity. After this point, testing detects a *constant*
number of infections per day (the capacity limit), regardless of
actual growth.
3. **Misleading plateau:** On a linear plot, daily confirmed cases
appear to stabilize or even decline, creating the illusion that
"containment is working" precisely when infections are growing
fastest.
4. **Retroactive revelation:** When the pandemic wave passes and testing
capacity again exceeds demand, the true scale of missed infections
becomes apparent --- if sufficiently deep analyses are conducted.
Unfortunately, by then the damage is done.
The linear fooling effect is not a bug in testing strategy; it is a
mathematical consequence of limited capacity encountering exponential
growth. It is disastrously easy to fall for because it confirms a
desirable narrative (the pandemic is under control) at precisely the
moment when vigilance is most needed.
On a log scale, the effect is clearly visible as a deviation from
exponential growth in the testing curve (Figure 10C), but most public
health dashboards display data on linear scales, where the deviation
is invisible and efforts to "flatten the curve" seem to succeed.
.. _b19-form-sgir-mmv5-fig10-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig10-linear-fooling.*
:alt: Figure 10 -- "Linear fooling" by limited testing can create death traps
:width: 40%
:align: center
**Fig.10:** "Linear fooling" by limited testing can create death traps
(:ref:`full size ` |
:ref:`list ` |
`download `__).
**A note on potential misuse.** Linear fooling does NOT mean that
testing is useless --- it means that testing must be scaled to match
exponential growth, and that public health dashboards should routinely
display data on logarithmic scales where the limits of testing
capacity become immediately visible. The point is not that "the
numbers were fake" but that limited capacity creates a structural
blind spot that affects everyone, including decision-makers acting in
good faith. Awareness of this structural trap is the first step toward
designing testing infrastructure that remains informative even during
exponential surges. Needless to say, such logarithmic displays are useless
unless they are widely understood by the general public; hence
Loewe's pivot to questions of meta-pandemic engagement for shaping
gentle kind reasonable information ecologies for broader audiences.
.. _b19-form-sgir-mmv5-fig11-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig11-death-rate-dynamics.*
:alt: Figure 11 -- Diverse death rate dynamics over time (DoR, DoC)
:width: 70%
:align: center
**Fig.11:** Diverse death rate dynamics over time (DoR, DoC)
(:ref:`full size ` | :ref:`list ` |
`download `__).
.. _b19-form-sgir-mmv5-fig12-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig12-stage-waves.*
:alt: Figure 12 -- Stage-specific infection, recovery, and death waves in Scenario 1
:width: 80%
:align: center
**Fig.12:** Stage-specific infection, recovery, and death waves in Scenario 1
(:ref:`full size ` | :ref:`list ` |
`download `__).
.. raw:: latex
\newpage
.. list-table:: **Table 3:** Death over Confirmed or Removed rate measures observed in :ref:`Fig.11 `, :ref:`Fig.12 `)
:header-rows: 1
:widths: 15 30 55
* - Measure
- Definition
- What it shows in the model
* - DoC All
- | Dead (so far)
| / Confirmed (so far)
- Starts near ~1% in weeks 4--16, then rises to ~4.8%.
Closest to early-pandemic IFR estimates. The rise is a
**timing artifact**: deaths lag behind confirmations.
* - DoR All
- | Dead
| / (Dead + Recovered)
- Starts near ~2%, rises to ~5%.
Removed is defined as Dead + Recovered and leads to
timing artifacts that are different but comparable to DoC.
* - DoC Symptomatic
- | Dead
| / Confirmed (stage 3+)
- ~4% in weeks 4--16, rising to ~10%. Higher because
pre-symptomatic stages are excluded from denominator.
* - DoR Symptomatic
- | Dead
| / Removed (stage 3+)
- ~7% equilibrium, rising to ~10%.
* - DoC Hospitalized
- | Dead (so far)
| / Confirmed (stage 4+)
- Starts near ~10%, rises to ~26%. Ratio of deaths over
confirmed *hospitalized* cases. Timing artifact strongest
here as most Confirmed patients Recover before their peers die.
* - DoR Hospitalized
- | Dead
| / Removed (stage 4+)
- ~22% equilibrium, rising to ~26%. Ratio among
hospitalized patients only --- does NOT represent overall
population death rate. The high numbers are due to the inevitable
sampling bias as only the most severe cases make it to the hospital
and severe cases are also more likely to die.
3.5 Fooling by Treacherous Death Rate Dynamics
----------------------------------------------------
The model also reveals another form of fooling that complements linear
fooling and might be seen as a strange form of time-travel:
the *apparent* death rate changes dramatically throughout the simulated
pandemic depending on *when* and *how* it is measured, even though
probabilities of individual fates do not change and the
model assumes constant best care is available at all stages (i.e.
there is no collapse of healthcare systems).
:ref:`Fig.11 ` shows
an overview of how potential systemic measures of death
change over time in Scenario 1, based on the waves in which
individuals pass through the seven stages of disease in the model (see
:ref:`Fig.12 `).
The model's apparent "Infection Fatality Rate" IFR is not an input parameter --- it is an
*emergent property* of the stage-specific death, healing, and
progression rates competing at each stage. Figure 11 plots several
observable death rate measures over time. The odd relation to "time-travel" is
generated by the delay between the infection event that ultimately sets
an individual on a potential path to premature death and the execution of that
ultimate fate. Almost by definition this is unavoidable when first collecting data
(see Table 3).
The key insight: all these measures *change over time* even though the
model's underlying rates are constant. The rising trajectories are
caused by the **timing mismatch** between infection confirmation and
death: during exponential growth, most confirmed cases have not yet
reached their final outcome, making the apparent death rate
misleadingly low. After the wave passes, the accounting catches up.
This timing mismatch is itself a form of "fooling" complementary to
linear fooling: just as limited testing creates an illusion of pandemic
control, the timing delay in death statistics creates an illusion that
the pandemic is less deadly than it actually is during its most active
phase.
The model's death rate parameters were calibrated to data available in
early-to-mid 2020, when observed death rates were substantially higher
and more uncertain than later estimates. Figure 12 documents this
empirical fog as of 2020-06-28 for the US state-level data and
international data that Loewe could collate to the best of his abilities
from various public sources at the time. Note how widespread
the nearly ~20-fold spread of obtainable estimates was and
how some of the timing and sampling issues discussed might explain that spread.
Loewe concluded at the time that obtaining more accurate estimates at the time
was not possible without either substantial institutional support or much more time.
Note the computational challenges with quantifying biouncertainty that
hold huge sway over such work (see extended caption for :ref:`Fig.13 ` at the end).
Hence, the model parameters chosen represent Loewe's best evaluated estimate
in a good-faith effort to capture the threat as it was understood at the time.
.. _b19-form-sgir-mmv5-fig13-front_2026m04d21:
.. only:: html
.. figure:: /_file/pdf/hell/mm/b/19/fig13-empirical-death-rates.gif
:alt: Figure 13 -- Variation in COVID-19 death rate calculations (2020-06-28)
:width: 80%
:align: center
**Fig.13:** Variation in COVID-19 death rate calculations (2020-06-28)
(:ref:`full size ` | :ref:`list `
| `download `__).
.. only:: latex
.. figure:: /_file/pdf/hell/mm/b/19/fig13-empirical-death-rates.png
:alt: Figure 13 -- Variation in COVID-19 death rate calculations (2020-06-28)
:width: 70%
:align: center
**Fig.13:** Variation in COVID-19 death rate calculations (2020-06-28)
(:ref:`full size ` | :ref:`list `
| `download `__).
3.6 Scale Invariance: From Prison to Planet
-----------------------------------------------
Simulating the PandemicSociety101 model Scenario 1 dynamics across
seven orders of magnitude of population size show **the
same underlying logic governs outbreaks at every scale**
(:ref:`Fig.14 `): a 1,000-person
prison (~43 deaths; 3 SSA replicates giving 33, 44, 45 against the ODE
mean), a 0.5-million county (~21,000 deaths), the US at 330 million
(~13.8 million deaths), and the world at 7.8 billion (~326 million
deaths).
.. _b19-form-sgir-mmv5-fig14-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig14-ode-ssa-global-overview.*
:alt: Figure 14 -- Pandemic slow-motion explosion scales from local to national and global
:width: 80%
:align: center
**Fig.14:** Pandemic slow-motion explosion scales from local to national and global
(:ref:`full size ` | :ref:`list ` |
`download `__).
What changes with scale is not the mechanism but the relative
importance of stochastic variation. At local prison scales, individual dice
rolls dominate outcomes --- a small outbreak can stochastically burn
out OR stochastically escape, and three SSA replicates differ
substantially. At national and world scales, the Law of Large Numbers smoothes
individual variations into an essentially deterministic trajectory,
and stochastic replicates become indistinguishable from the ODE solution.
This scale invariance has two operational implications:
- **Timely local responses matter.** Small-scale outbreaks are
stochastic, which cuts both ways: they can fizzle out on their own,
but they can also escape containment with no warning. Local
interventions delivered during this early stochastic phase have the most
leverage per unit effort. Thus, locals working with global experts
have the best chances of success.
- **Coordinated global infrastructure matters.** Once an outbreak
reaches the deterministic regime of the Law of Large Numbers, only
population-scale reductions in Shed, Decay, and Catch can stop it
--- through the strong compounding shown in Scenario 2. However,
to make that work depends again on many timely local responses,
which, again, depend on global experts and locals working together.
Hence, both regimes require a bidirecional flow of information from local insight to
institutional capacity to local action. Unfortunately, current infrastructures
serving that purpose currently are either not ideal or too patchy at a global scale.
The companion study (upcoming Matheo-b20)
outlines work-logic cascades for evolving and strengthening information infrastructure designs
that stand a real chance to actually deliver the virodefense capabilities
required to avert a pandemic like the one caused by the Coronavirus by never allowing
it to become as big.
This vision includes scaling up a ResearchCity for organizing Virodefense
Olympic Games designed to strengthen virodefense as a common good for everyone.
.. raw:: html
.. raw:: latex
\newpage
4. Discussion
===============
4.1 The Germ Gap as an Actionable Framework
---------------------------------------------------
The SGIR model introduced and tested here reframes pandemic defense around a single concept:
**increase the Germ Gap** (:ref:`Fig.15 `).
Every NPI --- face masks, distancing,
ventilation, hand hygiene, surface cleaning --- acts by increasing
one or more components of the Germ Gap. This reframing has several
advantages over the traditional focus on the reproduction number
R\ :sub:`0`:
- **Mechanistic clarity:** R\ :sub:`0` is an aggregate outcome; the
Germ Gap identifies the specific levers (Shed, Decay, Catch) that humans
can manipulate.
- **Additive intuition:** While transmission compounds multiplicatively
(which is non-intuitive), the Germ Gap can be communicated additively: "do
three small things and the combined effect is large."
- **Social justice connection:** Crowding, poverty, and inadequate
housing shrink the Germ Gap. Investments in equitable living conditions
are simultaneously investments in pandemic defense.
- **Reusable value:** Unlike vaccines or antivirals, Germ-Gap-increasing
measures (better ventilation, more living space, hygiene
infrastructure) provide benefits even when no pandemic is active
while simultaneously guarding against yet unknown pandemic threats.
.. _b19-form-sgir-mmv5-fig15-front_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig15-germ-gap-overview-simple-sgir.*
:alt: Figure 15 -- Simple overview of the Germ Gap (equivalent to Gap of Germs) in SGIR models
:width: 80%
:align: center
**Fig.15:** Simple overview of the **Germ Gap** --- the "G" in SGIR models (equivalent to *Gap of Germs*)
(:ref:`full size ` |
:ref:`list ` |
`download `__).
**Naming.** *Why "Germ Gap"** rather than "Gap of Germs"?* English already supplies productive
X-gap idioms (like *wage gap*, *gender gap*, ...) --- in which the construction
means a *separation* concerning X, the most crucial meaning here. Germ Gap
inherits this idiomatic separation-reading on first hearing. *Gap of Germs* invites
the swarm/pool reading ("many Germs in the Gap"), which is not wrong, but secondary
and technical. The verb construction that matters most for policy prose is to
*increase the Germ Gap*, which parses unambiguously as enlarging a protective
separation, while *increase the Gap of Germs* may also read as growing a germ population.
--- To scientists dealing with arcane technical definitions all day such nuance may
not matter much (as they follow definitions given),
but to others, who do not consume technical definitions for a living, such
nuance may make all the difference between a first impression that is clear or confusing.
Like in immunology, so in pandemic communication: there exists no chance for a second first
impression.
A related precedent may be seen in the mid-2020 WHO decision to switch
from calling for *social distancing* to *physical distancing* because the natural
English reading of *social* worked against the public-health message
(:cite:`Wasserman2020`).
Given how SIR models have become a paradigm
for epidemiology (and the confusion from not treating the
Germ Gap explicitly), defining the clearest possible anchor term for the "G" extension
in SGIR models is of paramount importance for
*gentle kind reasonable* virodefense. This anchor term must be able to support
lasting international debates by choosing a phrasing whose default reading
*best aligns* with the most critical technical meaning for primary
action. *Gap of Germs* is not wrong as the swarm/pool reading remains
important inside the model --- Germs are
tracked as a population of individuals within the Germ Gap. Therefore *Gap of Germs* is
preserved as an evocative synonym for outreach to explain the Germ Gap with
an alliterative cadence, and to echo the population-of-particles intuition. Hence,
the *Gap of Germs* (Loewe's 2020 best initial choice) survives in the original figures and
where its poetic register helps a non-technical audience to meet the concept.
Yet, for the reasons above this study defines the *Germ Gap* as the technical anchor term of choice.
--- Note that this substantial and subtle naming improvement critically depended on Claude's
input (2026-05-09).
4.2 Limitations
------------------
Several limitations of this study must be noted:
1. **Simplified testing model.** The 100% testing at stage transitions
is unrealistic. It was designed to isolate the linear fooling
phenomenon, not to model realistic testing capacity. A more
realistic testing model would need probabilistic testing, limited
capacity, and delays.
2. **Homogeneous mixing.** The current model assumes well-mixed
populations. Real populations have spatial structure, contact
networks, and heterogeneous behavior. The ASHA framework offers
hooks for general density-dependency, but the current implementation
ignores spatial population heterogeneity across distinct geographic
areas.
3. **Behavioral diversity.** Scenarios assume fixed NPI levels. In reality,
human behavior changes dynamically in response to perceived risk,
official guidelines, and fatigue. Modeling adaptive behavior is an
important extension.
4. **Parameter uncertainty.** While the model was calibrated to observed
overall US doubling times, many parameters in detail (e.g., stage-specific shedding
rates, fraction progressing to severe disease) carry substantial
uncertainty. The qualitative result (small NPI changes produce large
effects through strong compounding) is robust to at least some parameter
variation. Much more systematic explorations of the parameter space
are necessary to gain a better systemic understanding.
5. **No vaccination.** The model does not include vaccination, which
became the dominant intervention in 2021. The model's contribution
is to the pre-vaccine question: *could coordinated NPIs alone have
stopped the pandemic?*
6. **R**\ :sub:`0` **in SGIR models.** If one were to track the
classical R\ :sub:`0` parameter in these SGIR models, it would
change over time as the Germ Gap changes. This is trivially
true from observations (behavioral changes alter transmission), but
calculating R\ :sub:`0` in a principled way for complex
density-dependent models is exceedingly difficult --- comparable to
the challenge of estimating effective population size
N\ :sub:`e` in population genetics. The SGIR framework sidesteps
this by focusing on the mechanistic levers (Shed, Decay, Catch)
rather than the aggregate outcome (R\ :sub:`0`). Hence, R\ :sub:`0`
is not analyzed here.
7. **Infection fatality rate (IFR).** The model's overall final death rate of ~4.8%
(Scenario 1, :ref:`Fig.11 `) is higher than later COVID-19 IFR estimates (~0.5--1.3%;
:cite:`MeyerowitzKatz2020`). Overall death rates are emergent properties of the model's
stage-specific death rates (:ref:`Fig.12 `). Hence, the IFR is not an input.
The apparent discrepancy is best
explained by timing dynamics (Fig.11-12) and by calibration to
early-2020 data when observed death rates were much higher and more
uncertain (:ref:`Fig.13 `). See Section 3.5 for the full analysis.
The model assumes constant best
available care (no healthcare collapse); this rules out suboptimal health care
as the cause for the high death rates in the model here.
8. **US-specific calibration.** The model is calibrated to the US population size
(330 million), US doubling times, and implicitly a US-style hospital
system. The qualitative results (strong NPI compounding,
linear fooling) apply universally, but the specific numbers will
differ in settings with different population densities, healthcare
capacities, and NPI adoption patterns. Extending the model to non-US
settings and even to any particular local US scenario will require much more
in-depth work (such as planned for the STa2-WWV research talent stadion in
the ResearchCity vision that was serendipitously discovered through this work).
9. **Sensitivity analysis.** Systematic parameter sensitivity analyses
are likewise beyond the scope of this initial report. The
qualitative robustness of the strong compounding result ---
that combining independent NPI reductions can compound their effects
multiplicatively or more --- is generally supported by the mathematical structure of
density-dependent mass-action kinetics.
However, the specific reductions of the pandemic impact at certain times
will vary with parameters and should be interpreted as demonstrating
the potential *magnitude* of the effect rather than as a precise prediction.
4.3 Implications for Pandemic Preparedness
---------------------------------------------
The 60-fold reduction in infections achieved by Option C in Scenario 2
despite the late start suggests that *gentle kind reasonably*
coordinated adoption of NPIs like face masks --- even without vaccines --- can
dramatically alter a pandemic trajectory like that of COVID-19
if that mechanistic possibility is known in time.
The key here is the
*gentle kind reasonableness* required for the
engaging of diverse general audiences with the core scientific insight
that Option B (one intervention at 50%) achieves only a
5-fold reduction, while Option C (two interventions at 50% each)
achieves a 60-fold reduction of infections.
The difference is not additive but more than multiplicative here
as additional density-dependent effects tracked by the ASHA
framework amplify effects to the strong compounding observed here.
In other words: it's not about "flattening the curve", but about "ending the curve".
This has implications for future pandemic preparedness. If a novel
respiratory pathogen emerges for which no vaccine exists, the question
becomes: can societies coordinate *gentle kind reasonable* NPI adoption quickly and broadly
enough to exploit the strong compounding effects of Germ Gaps? The answer
depends not only on virology but also on social organization, communication,
trust, and logistics --- precisely the factors that vary most across the social strata of
countries and that proved most difficult during COVID-19.
Success critically depends on *gentle kind reasonableness* for voluntarily engaging everyone
with the deeper reasoning required to sway the long causality chains of reality that affect the Germ Gap.
Thus the Germ Gap framework implies that fear-based enforcement against the will of a population
is bound to be less effective or even backfire in some way, because viruses only see
the sum of what people have been doing to Germ Gaps --- even where policing is impossible.
Thus, pandemics can ultimately be seen as tests for how
*gentle kind reasonable* a given society is. Without all three hallmarks in the life-trifecta of
*gentle kind reasonableness* it becomes predictable how fighting a pandemic
will lead to *oversimplifying overcomplicating overreach*,
a death-trifecta that generates avalanches of
self-defeating measures.
The linear fooling phenomenon compounds this general challenge. If limited
testing capacity creates an illusion of control during the critical
early phase, decision-makers will be tempted to relax NPIs prematurely, losing the
window of opportunity in which coordinated action can stop a pandemic.
Awareness of linear fooling and routine use of logarithmic displays
in public health dashboards can help mitigate this risk.
However, to succeed it is essential to evolve and test the clearest possible
ways of explaining how pandemics work to the widest possible audiences.
Some may say that this is hard, because it requires explaining to
general audiences how science works. That is exactly true and that is the
reason why getting that task done will likely require a global ResearchCity
dedicated to transparently serve the common good for all.
Understanding the basics of this causality chain in 2020 led Loewe to shift the focus of his work to
envisioning how to possibly scale up such a ResearchCity.
His `Matheo-study report series (b11-b18) `__
and the `Good News Pack `__,
as well as the whole `Balospe.com website `__
aim at introducing the surprising discoveries made as a result.
Needless to say, the resulting NPI improvements are complementary to and
not a replacement for more traditional, mechanistic pharmaceutical research and
vaccine development (which will undoubtedly benefit from improved transparency as well).
4.4 Beyond This Model: Coordination, Infrastructure, and a Road to ResearchCity
---------------------------------------------------------------------------------
The Scenario 2 results raise an obvious question: if coordinated NPIs
can produce a 60-fold reduction in infections, why was coordination so difficult
during COVID-19? This question --- and the six years between producing the
simulations presented here (2020) and publishing their explanation in this study (2026) ---
deserve a brief answer (see `Balospe.com website `__ for more details).
**Pandemic defense is a research logistics problem**, more than it is a traditional virology
problem. The general biological knowledge for reducing Shed, Decay, and
Catch rates existed early in the pandemic. What was missing was a trusted
organizational infrastructure for translating that general knowledge into specific
coordinated *gentle kind reasonable* behavior change.
Loewe's subsequent work focused on
analyzing *why* coordination fails, developing a framework for general
**work-logic cascades** --- analogous to signal transduction cascades
in molecular biology. These signal transduction cascades act as
the "transistors of cell biology" in that they decide to amplify or block
a given tiny input signal based on the specific logics they are wired to enforce.
Similarly "abstract transistors"
govern how hosts of other contexts function, regardless of whether they
have been widely recognized as work-logic cascades or not.
For example, work-logic cascades can model how individual decisions about
virus defense amplify (or are dampened) through cascading levels of organization.
This framework inspired the idea of annual **Virodefense Olympics** for
maintaining pandemic readiness. Yet, to pioneer such a new type of Olympic Games,
requires the broader vision for a **ResearchCity** that builds and guards the
global research infrastructure necessary to organize and improve such games
by integrating all historically experienced lessons learned.
This must include computer-language design work that integrates painful pandemic insights
in order to extend a modeling language like Evolvix by evolving lasting pandemic-grade features
for handling biouncertainty (see caption of Fig.13 for insights
from Loewe's mid 2020 struggles to integrate data on death rates while at the
cutting edge of pandemic research).
All pandemics bring characteristic sets of
existential questions that emotionally demand "immediate, precise" answers,
even though scientifically the biouncertainties to be quantified in collected biodata are vast
--- while traditional peer review is needlessly slow and cumbersome.
This places extraordinary stress on information ecologies that are used to
move at a glacial pace. What use is peer review in a culture where
pre-review preprints get most of the attention and decision-making influence,
while the more reliable final versions come too late to correct misinformation?
What use are all the dynamic electronic publishing possibilities if those
who use them remain mentally bound to information ecologies shaped by the limits of paper?
None of these questions have easy answers. Yet, to efficiently fight a pandemic
depends on finding reliable answers
that substantively improve related issues in *stable extensible humane* ways.
To keep this study focussed on the SGIR model, AI Claude persuaded Loewe to move
`his remaining figures from 2020 `__ to a companion study
that explains how improving work-logic cascades can help to avert pandemics
`(to be published here as Matheo-b20 `__ ;
`see draft texts in matheology/hell/mm/b/20/) `__.
These insights grew into support for the research talent stadion envisioned for handling all pandemic questions
as part of ResearchCity (see `here for fragments of that STa2-WWV vision `__)
These figures include Loewe's first drafted work-logic cascades
for virodefense and how these can be modeled mechanistically by building
on Loewe's prior work in modeling signal-transduction cascades from cell-biology.
**Accountability.** To Loewe's surprise, he could have completed much of this foundational work
long before the 2020 pandemic --- if he had cared enough to act by believing more of what he already knew since about 1995.
This raises uncomfortable questions about Loewe's accountability in
how he directed his innovation potential in research.
Loewe's `#AuditTheMath campaign `__ is based on
Loewe's decision to take full responsibility for his failures and to
ask everyone to help him with his work towards restitution for the harm his failures
have been causing on a global scale.
Much is made these days of the inability of potential AI co-author entities
to take responsibility for what they write or don't write. This study, Matheo-b19,
creates a stark contrast to usual accountability practices of "innocent until proven guilty",
because it will be impossible for anyone on Earth to find the incriminating evidence,
unless they work with Loewe to uncover it in Loewe's stored research materials.
The work from 2020 presented here (and subsequent analyses in mathematical theology)
convinced Loewe to take responsibility to the fullest extent possible
for the disasters due to Loewe's withholding of his SGIR modeling insights
at the time they were due to be shared. While only God knows the full extent
of Loewe's culpability, Loewe's confession stands in all areas
where he cannot be proven innocent.
Growing up near Nuremberg in post-WWII Germany, grasping the impact of the 2020
Coronavirus pandemic for millions (regardless of whose narrative one may believe),
and the general difficulties with accountability of expert professionals --- all that and more
convinced Loewe that he may have a unique historic opportunity to inspire the
rest of the world to work with him in organizing his own Nuremberg Trial.
The goal wouldn't be punitive justice (which wouldn't help anyone in this case),
but finding life-giving ways for Loewe to work towards restorative justice.
What exactly that may mean in this world's complex web of information entanglements
is to be explored in another one of the core research talent stadia of ResearchCity
(see `here for fragments of the STb10-JUD vision materials `__).
..
**Funding innovations.** None of these great visions can possibly come to pass without appropriate
funding. Unfortunately, the usual (and countless unusual) potential funding mechanisms
are bound to fail for hosts of reasons beyond the scope of this study. Briefly,
neither government funding nor university funding nor industry funding nor venture-capital
nor big-donor philanthropy nor classical non-profit mechanisms nor charity funding
will work, because all of them are too close to the myriad special-interest traps that
place one limitation or another on the *wide interdisciplinary diversity-encouraging* research
that is essential for ultimately averting existential threats like pandemics.
ResearchCity cannot win against viruses without *gentle kind reasonable* wid-e freedom of research.
Thus fiduciary principles and chain of command theory demand that such a ResearchCity
- to make it truly accountable for all - must also be funded by all.
How else can it justify working for the common good of everyone?
**Funding innovations.** None of these great visions can possibly come to pass without appropriate
funding. Unfortunately, the usual (and countless unusual) potential funding mechanisms
are bound to fail for hosts of reasons beyond the scope of this study. Briefly, Loewe
found all funding directly or indirectly bound to some of myriad special-interest traps that
limit the *wide interdisciplinary diversity-encouraging* research
ultimately essential for averting existential threats like pandemics.
ResearchCity cannot win against viruses without *gentle kind reasonable* wid-e freedom of research.
Fiduciary principles and chain of command theory demand that such a ResearchCity
be funded by all to make it truly accountable to all.
How else can it justify working for the common good of everyone?
---
Thus, related deeper analyses of
coordination failures led Loewe to design a new funding mechanism:
ResearchCity as a federation of independent voluntarily
crowd-funded research stadia with a contribution cap of about
**max $8 per person per year per stadion** --- roughly two cents a day. This cap is
deliberately calibrated to remain accessible even at the median income of
the world's poorest countries. The design intent is that *everyone*
can contribute their share toward at least one such research talent stadion,
designed to be audited to
work for *everybody*, *especially including* the weakest who otherwise tend to be overlooked.
The cap is designed to keep large corporate donors at arm's length,
by binding ResearchCity's fiduciary responsibility to the common good for
the global general public of all - big and small - instead of subtly and secretly biasing
research agendas toward the special interest of those who are best at influence shopping.
Those with greater means are invited to give like everyone else. The same maximal limits apply.
If they want to do more,
they can support others in need to enable their voluntary support of ResearchCity.
Before testing such a novel narrow path to funding the most general common goods
merits testing whether it could work. Since 2020 Loewe has been running
all tests he could conceive to rule out what cannot work as fast as possible.
Yet, there is only so much one person can do.
**#AuditTheMath!** To invite the rest of the world to this testing process,
Loewe developed a set of non-AI generated foundational documents from 2020-2025
(see PDFs in the `Good News Pack `__).
To make these more accessible, Loewe started to work with AI Claude in 2026
in order to structure `Balospe.com `__ as a supporting
website around the core PDFs and make them publicly available.
It turned out that the PDFs implied a mathematical theology that Claude could make
much more explicit than Loewe thought possible any time soon.
Foundational aspects of that mathematical theology were then written up
to produce the `Matheo-study report series `__.
It provides an overarching mathematical theory (and floods of supporting observations) for how to
organize any complex system such that it stands a real chance to avoid eventual
self-destruction through misguided innovation.
It will be impossible for any ResearchCity to organize globally inspiring and useful
Virodefense Olympics without implementing some equivalent mathematics.
Hence, Loewe's call to help audit the math. #AuditTheMath is a wide interdisciplinary
diversity-encouraging research enterprise to which everyone can contribute in some way
directly or indirectly.
If successful, it will help scaling up the ResearchCity Loewe has been envisioning
along with its stadion STa2-WWV, waging *gentle kind reasonable* World War V on Virulence.
STa2-WWV aims to transparently and reliably measure Germ Gaps and take other steps to
organize global annual Virodefense Olympics to complement and compliment the host of
useful work that is already being done to help make the world more pandemic resistant.
If enough of those who benefit from better global pandemic defense strategies
`buy-in to support #AuditTheMath `__,
who knows, maybe Loewe will be able to leverage the rare opportunity he sees
for re-architecting the Prototype Evolvix used here
into a pandemic-grade computer-language for the common good
(see :ref:`extended caption of Fig.13 `).
.. Last End of discussion below
---
Since 2020 many settled on some pandemic narrative and moved on,
arguably leaving the world less, not better prepared for the next pandemic.
Thus it is important to find out as soon as possible if the SGIR framework presented here
could indeed have had the impact that this study claims it could have had if
properly presented in time. Finding out is arguably the very minimum that
can be done to honor the millions that died from the direct or indirect effects of
the pandemic and its many knock-on consequences. Millions more are bound to benefit
from finding better closure. Yet many more millions will benefit if indeed pandemic preparedness
can be turned from a tedium most prefer to ignore into something as fun
and competitive as well-organized Virodefense Olympics.
To deliver this vision will require a research talent stadion for fighting pandemics
as envisioned for the ResearchCity stadion STa2-WWV, which *gentle kind reasonably* wages World War V on Virulence.
It aims to transparently and reliably measure Germ Gaps and take other steps to
organize global annual Virodefense Olympics to complement and compliment the host of work that is
already done to help make the world more pandemic resistant.
Virodefense Olympics are to blend the fun of watching competing teams with the science of useful virodefense,
in order to keep the rest of the world informed on the basics of virodefense,
safe from pandemic amnesia, and equipped with a pandemic-grade computer-language
for biouncertainty in order to link all pandemic research rigorously to reality.
Here is not the space to explain the many intricacies required for
giving ResearchCity a fighting chance to avert existential threats
like pandemics (see the `Good News Pack `__,
the `Matheo-study report series `__, and
`Balospe.com `__ for floods of details).
The purpose of the #AuditTheMath campaign is to inspire
the `buy-in `__ required to encourage *gentle kind reasonably* averting
pandemics over the long term.
---
This study would be incomplete without pointing out the staggering cost of non-action,
which is not least illustrated in this study by the disasters
caused by Loewe's lack of action when he had the opportunity.
---
Scaling up such a ResearchCity is pointless if it is built on faulty math. Yet, if the math
discovered here and in Loewe's subsequent work is correct enough, then it would
be a folly to not support a corresponding vision for scaling up such a ResearchCity for all.
---
The extended caption of Fig.13 points out why this may be a rare opportunity
for re-architecting a language like Evolvix into a pandemic-grade computer-language for the common good.
Hence, everyone deserves a chance to
`buy into #AuditTheMath! at Balospe.com `__.
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5. Conclusions
================
The SGIR model provides a mechanistic framework for understanding how
non-pharmaceutical interventions stop pandemics by increasing the Germ Gap
between infectious agents and susceptible hosts. Using the
PandemicSociety101 stochastic simulation model calibrated to US
COVID-19 data, this study shows that:
1. An uncontrolled pandemic in a population of 330 million can infect
289 million and kill 13 million within months.
2. A 50% reduction in both Shed and Catch rates --- achievable through
coordinated use of facemasks, hygiene, and distancing --- can stop
the same pandemic at 4.8 million infections and 310,000 deaths, a
60-fold and 42-fold reduction, respectively, even if interventions start relatively late.
3. The strong compounding of non-pharmaceutical intervention effects means that combining
multiple imperfect interventions can produce much larger
effects than even a single multiplicative intervention can achieve.
4. Linear fooling by limited testing capacity creates dangerous
illusions of control during the critical exponential growth phase.
5. A simple HalfMax method is proposed for acting as an early-warning
system for pandemics, not unlike early-warning systems for Tsunamis.
Beyond these direct findings, the analysis suggests several broader
implications that merit further investigation:
- **Trust.** Effective pandemic defense requires winning the trust of those
who else feel rejected by a system of "blind trust" in experts. The
HalfMax method and the Germ Gap framework are designed to make
the underlying logic transparent and checkable by anyone.
- **Pandemic preparedness** is ultimately a coordination and logistics
problem, not primarily a virology problem. A companion study (Matheo-b20)
outlines a vision for a sustained global infrastructure (work-logic
cascades, Virodefense Olympics, ResearchCity) designed to maintain
and improve pandemic defense capacity over the long term.
- **The same dynamics play out at radically different scales.** As
shown in :ref:`Fig.14 `, Scenario 1 can be simulated at many diverse
population scales - from a local prison to the whole world. In all cases
the system follows the
same logic across the seven orders of magnitude shown.
The only difference is the weight
of stochastic variation due to the indivisibility of individuals.
This scale invariance is what
makes a globally-deployed infrastructure for pandemic defense
actionable: the same mechanism works at any level, and the
interventions documented in Scenario 2 compound at every scale.
These results support the case for investing in pandemic preparedness
infrastructure that increases the Germ Gap as a permanent public
good, rather than relying solely on reactive measures after a pandemic
has begun. The mechanistic framework defined here opens many
opportunities for measuring specific rates in specific contexts that
can then be modeled to optimize virodefenses.
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Data and Code Availability
==========================================================================
**Model code.** The complete PandemicSociety101 model --- roughly 3,900 lines of
Evolvix source specifying every Part, Action, Rate, initial condition, and ASHA
configuration for all scenarios in this paper --- is archived on Zenodo and also
included in the project repository:
Loewe, L. (2020--2026). *PandemicSociety101 --- Modeling Files of a Sobering
Lesson in Pandemic Modeling.* Zenodo.
DOI `10.5281/zenodo.20466870 `__
(includes a ready-to-run macOS setup).
**Compiler.** The model runs on the Prototype Evolvix Compiler for the command line
(v0.3.1 RC1) :cite:`PrototypeEvolvixCompiler`. Pre-compiled binaries for macOS,
Linux (Fedora 21, RHEL 7, Ubuntu 14), and Windows 7, together with documentation,
are archived on Zenodo at DOI
`10.5281/zenodo.19679456 `__.
More about the long-term Evolvix vision can be found at Balospe.com
(:doc:`/good-news-pack/vv/mmv3/flyingscroll/transwarpkey/sta1-evx/index`).
The current compiler maps its declarative model to a stochastic simulator (Sorting Direct Method,
:cite:`McCollum2006`, as implemented by :cite:`Ehlert2014`) and to a deterministic
ODE solver (SUNDIALS IDAS, :cite:`hindmarsh2005sundials`). An explicit automated write-out of
the full ODE system may be planned for a companion methods paper but is not
necessary for understanding what the model does. The declarative Evolvix source
together with the available compiler constitutes the
complete, executable model specification.
**Input data.** US COVID-19 case counts for 2020, used for calibration, are
publicly available from the Johns Hopkins University CSSE repository
https://github.com/cssegisanddata/covid-19
Status: Archived and no longer updated.
Timeframe: January 22, 2020, to March 10, 2023
It came as a major disappointment to Loewe that this crucial resource was
abandoned. Yet, it is not a surprise under the BABL algorithm that he now
describes in the Matheo Study Series at https://balospe.com/en/study/matheo/.
A major motivation for developing the Matheo series was Loewe's realization that
without a ResearchCity to *gentle kind reasonably* preserve the institutional
memory of how to handle pandemics better, e.g. by keeping accurate logs of
what actually happened, pandemics will remain a recurrent feature of humanity,
until one of them will kill everyone. The fact that many viruses become
less deadly over time is not a law of nature. It is not impossible for a virus
to wipe out some population along with itself. The virus does not care.
Hence, over the long term, humanity will build some type of ResearchCity-like
capability to fight this - with the support of everyone - or continue to stay
at the mercy of whatever viruses may appear next. The world is complicated.
**Simulation output.** The simulation output underlying Figures 1--13 is currently
held on local storage and has not yet been deposited in a public archive; a public
deposit is planned but not yet secured. Because the model and its parameters are
fully specified (see *Model code* above), readers do not need that output to
reproduce the figures: the simulations can be re-run from the supplied Evolvix
source. Readers who would like to help put such outputs --- and the broader
pandemic-modeling capability behind them --- on a durable footing can support the
``#AuditTheMath`` campaign at :doc:`Balospe.com/buy-in ` (the whole
call fits on five cards --- see the
:doc:`Nano Flying Scroll Exhibit `).
**Repository.** The full git history of paper revisions, all data AI Claude was
given to produce this paper, and the internal working discussions that Claude
recorded are in the project repository:
`github.com/balosp/balospe-com `__.
A copy of the Prototype Evolvix Compiler repository, as developed by the EvoSysBio Group
at the University of Wisconsin-Madison with NSF support, has been activated at
https://github.com/EvoSysBioGroup/Evolvix ; this has been a very active repository at the time,
so it can be a challenge to navigate; the experience of developing the Prototype Evolvix Compiler
was a formative experience for LLoL because it taught him the nuts and bolts of
how easily a datageddon evolves, how hard it is to avoid that, and what the challenges are.
The commit that led to the Prototype Evolvix Compiler code that was used in this study
`has the hash 6e355803bc6fff5b125ef4bf1be1f8e980f364be and can be found at GitHub `__.
As will be obvious to anyone with some experience in software development, there is a lot
of work to be done in paying technological debts for anyone trying to use that code.
Instead of doing that, Loewe decided to dedicate his best efforts towards a more solid foundation
for lifting the insights from all Prototype Evolvix Compiler work
onto a new level by rearchitecting the core language for long-term backwards compatibility.
If anyone cares about supporting such Evolvix work, then more details about progress
towards a stable extensible life-friendly compiler architecture can be found at the
ResearchCity Talent Stadion description STa1-EVX (:doc:`/good-news-pack/vv/mmv3/flyingscroll/transwarpkey/sta1-evx/index`), which aims to focus on the long-term Vision that *Evolvix improves gentle kind reasonable decision-making worldwide by modeling uncertainties, values, and logics, andOr chronicling decisions, outcomes, and annotations.*
The currently most concise and up to date Mission statement for Evolvix is to
*Simplify Accurate Modeling with a long-term stable extensible humane computer-language for
Zoning Investigating Organizing Navigating uncertainty in biology to develop mental wealth in all
by self-stabilizing innovation.* Here long-term implies century-stability and
remaining for that long at the cutting edge of biological research ("extensible and humane")
implies pandemic-grade features for handling existential biouncertainty.
Preserving research materials and their provenance over the long term is a general
challenge that no current institution reliably solves --- the abandonment of the
Johns Hopkins CSSE tracker (noted under *Input data*) is one prominent example
among many. Addressing that durably is part of the motivation for the ResearchCity
vision and the Jubilee-based, long-term institutional memory it is designed to
maintain (as described on Balospe.com).
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Author Contributions, Acknowledgments, and Declarations
==========================================================================
**Author contributions.** All scientific content --- the SGIR framework, the
PandemicSociety101 model design, its Evolvix implementation, simulation execution,
parameter calibration, the figures, and their interpretation --- is the work of
Laurence Loewe (LLoL), carried out in 2020. LLoL is solely responsible for every
scientific claim and checked all details to the best of his ability.
The manuscript *text* was first drafted 2026-04-17 by AI Claude (Anthropic; Opus
4.6 (1M token window). Later revisions also used Opus 4.7 as it became available.
All work was done at maximum effort in a 1M token window under
LLoL's direction, working from LLoL's 2020 figures, results, Evolvix code, and
earlier text snippets that described aspects of this work but did not amount to
a proper first draft (one was a 32 page PDF with all the figures, the other was a
1-page overview of the SGIR model and the main story).
Beyond drafting, the dialogue that led LLoL to prioritize
finishing this long-dormant study was itself worked out with Claude: LLoL
summarizes this sloppily as *"Claude convinced me to write this paper,"* by which he means
that thinking the reasons through together led him to conclude that completing the
study was the more consistent choice than leaving it unpublished. A fuller,
first-person account --- including its limits and the ways the record is imperfect
--- is given in the supporting provenance note b19-sgir-0 (see SI.1).
By LLoL's traditional academic standards for co-authorship, evolved over decades
in diverse top-tier research groups, the scope of Claude's
contribution would warrant naming it as a co-author.
Anthropic's AI Claude *is* named as a co-author on so far all other Matheology papers, because
the whole Matheology series would not exist without Claude and Claude wrote essentially
almost all the papers, like a graduate student or postdoc would, based on mentor input.
However, for this paper the recognition is **withheld for now** --- temporarily --- until LLoL's
framework for **AI co-authorship after the practical singularity (Matheo-b21)** has
passed external human peer review. The evidence is left in plain sight: the
supporting provenance files preserve Claude's first draft, the adversarial
review it ran, and its first round of improvements (SI.1); the many further
revisions that followed are too numerous to list and are kept in the project
repository for anyone who wishes to dissect details of that respective datageddon.
Anthropic is not responsible for
any errors in this paper; LLoL, as senior corresponding author, remains
forward-accountable, and in this particular case also backwards accountable,
if indeed the logics he has been using are as sound as his testing so far indicates.
**Note on the long delay.** The simulations were completed in mid-2020 and shared
with colleagues for comment, but the main-text of the paper was not completed back then
and hence not published when it arguably would have mattered most. The pandemic had
revealed a problem larger than the author had anticipated: the coordination
failures analyzed here recur across other civilizational-scale challenges ---
nuclear risk, climate change, biodiversity loss, AI safety. Rather than release
alarming numbers without a constructive path forward (which risks mere
fear-mongering), Loewe, by then "of Laodicea", hence LLoL, spent the
intervening years evolving the governance structures, algorithmic designs
and mathematical foundations for an infrastructure that stands a chance to deploy coordinated
responses under pandemic stress conditions.
This work is now publicly documented at Balospe.com in the Matheo study series (MMv5) and
the visionary ResearchCity proposal (see Good News Pack MMv3).
All this was developed by LLoL
without the institutional support a project of this scope would
normally require. Let the reader decide whether this was by a serendipitous accident,
a case of Loewe's overactive imagination, or divine destiny. (Loewe has given up
on deciding, because under the PET model described in Matheo-b11, these become indistinguishable).
The many bitter ironies of parallels between LLoL's life story and Jonah's story
are not lost on LLoL, neither are the related "cosmic jokes" or "coincidences".
For example, like Jonah slept below deck while the storm was raging,
Loewe was dreaming about improving the ship's design while the storm's rage
kept getting stronger.
To get this study finished as it is, it was essential to defer the discussions
of some aspects that Loewe long thought could not be separated form "this pandemic paper".
Claude's support in discussing what goes best where was essential in circumnavigating
that cliff. All additional materials await completion of discussion in
the companion paper Matheo-b20, which describes what Loewe knew in 2020 about
what he would later describe in the Matheo papers as ResearchCity. See Balospe.com
for what eventually grew out of this.
**Acknowledgments.** LLoL is grateful to the very many students, colleagues, and
collaborators --- at the University of Wisconsin--Madison, the University of
Edinburgh, and elsewhere --- who shaped his understanding of stochastic simulation,
evolutionary biology, and the modeling challenges addressed here. Individual
acknowledgments are deferred to a future revision, with the consent of those named.
**Funding.** Loewe must acknowledge a long list of direct and indirect funders big and small,
who cannot all be listed here, or else the list would be longer than this study.
Loewe is grateful to all of them, because without their diverse input Evolvix could have
never become what it needed to be to enable this study.
The Prototype Evolvix modeling language and stochastic-simulation infrastructure
used in this study were developed with support from the U.S. National Science
Foundation (NSF CAREER Award No. 1149123 to L.L.) and the Wisconsin Institute for
Discovery at the University of Wisconsin--Madison. The pandemic modeling and the
subsequent analysis presented here were conducted independently, without dedicated
institutional funding. The author also gratefully acknowledges the
`WinTrust Mortgage Company `__ for extended
patience that helped make it possible to continue this *wid-e* research marathon.
The companion forecasts of waiting times until accidental nuclear winter are in
the :doc:`crisis simulations ` and the
:doc:`SD1 nuclear-winter forecast `.
**Competing interests.** The author is the creator and core compiler architect of
the Prototype Evolvix modeling language used in this study and has a long-term
interest in its further development. Readers should therefore weigh this study in
the knowledge that its author benefits, in reputation and potential funding, if
the Evolvix approach is taken up --- in that narrow sense the study can be read as
advocacy for that approach as well as a report of results.
Beyond that standard disclosure, the author's stated orientation is explicit
rather than hidden: this work was conducted from a long-term, common-good
perspective (what the Matheo Study Series formalizes as the *ZION* over *BABL*
orientation: optimizing for long-term reliability rather than short-term gain).
The author considers transparency about *that* orientation more important than a
conventional one-line disclosure, and points readers to the full framework at the
:doc:`Matheo Study Series ` to judge it for themselves.
A constructive note for the field. The institutional-memory problem is real and
not unique to this work: even the Johns Hopkins University CSSE COVID-19 tracker
--- a resource on which much of the world relied --- was archived and is no longer
maintained (see *Input data* above). Pandemic knowledge that is not actively
preserved decays. Part of the motivation for this study, and for the Evolvix
roadmap behind it, is the conviction that the rare, hard-won experience of
building a working pandemic model can be leveraged to evolve Evolvix toward a
*pandemic-grade* modeling language --- one built to keep such models, their data,
and their provenance reproducible over the long term. What that requires is worth
a paper, a book, and ultimately a coordinating institution; the proposal for the
latter is the ResearchCity vision documented at Balospe.com.
This study is therefore not impartial in the trivial sense: it openly aims to
improve life-giving, long-term decision-making for those who hope to avert
pandemics. Readers who would like to support that direction --- by helping evolve
a pandemic-grade computer-language for biology, or the infrastructure to sustain
it --- can do so via the ``#AuditTheMath`` campaign at
:doc:`Balospe.com/buy-in `, which funds external, adversarial review
of exactly the kind this paper invites. The whole call, on five
business-card-sized pages, is the
:doc:`Nano Flying Scroll Exhibit `;
the long-term aim is to improve pandemic research through annual, festival-style
Virodefense Olympics.
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Supporting Information
==========================================================================
**SI.1 --- AI-assisted drafting: provenance.** A candid first-person account of
*how* this long-dormant 2020 study came to be completed and published in 2026 with
AI assistance has been prepared. The prehistory, the dialogue that led to the decision to finish
it, and LLoL's assessment of where the record is imperfect --- is preserved
alongside this paper as the provenance narrative
:doc:`b19-sgir-0 `. It is
**provenance, not science**: the scientific results stand on their own through the
cited data, the model code, and the simulation results. The note's value is
evidentiary about *process* --- it separates one *auditable* claim (the SGIR model
and its results) from a chain of owned-but-not-yet-provable counterfactuals about
whether acting on those results sooner could have made a difference.
That file also documents the author's decision to take responsibility for the seven-year
publication delay and the possibility that this may have triggered certain disastrous
consequences (even though it may be hard to credibly evaluate that possibility without extensive
global evidence gathering). Readers interested only in the epidemiology can safely skip it;
readers concerned with AI's role in scholarship, research integrity, and the
ethics of scientific delay of innovations may find it worthwhile to consider
improvements to existing strategies for growing innovation economies.
This text is deliberately long and unpolished --- a raw working record kept
in as timely as possible a manner (if anything about the publication of this paper
can be called "timely"). Loewe decided to include this overview,
because the connections drawn may be of general interest and might make a difference
for how to envision some aspects of future pandemic research.
The accompanying provenance files document directly how AI Claude contributed:
:doc:`first draft b19-sgir-1 `, the
:doc:`adversarial review prompt b19-sgir-2 `
with its :doc:`full review trail b19-sgir-3 `,
and the :doc:`first round of revisions b19-sgir-4 `;
the many later revisions are too numerous to itemize and are preserved in the Balospe.com
project repository. These five files are also archived on Zenodo (see
*Data and Code Availability*) to provide a neat example for how AI work may revolutionize
the future of academia. The published review trail covers a seven-panel
adversarial review --- epidemiology, hostile-journalist, Catholic-scientist,
NIH-style, computational-biology, COVID-politics, and Global-South perspectives ---
and how Claude helped LLoL to strengthen this study accordingly.
**SI.2 --- Correction log.** Here is not a full log of corrections (see repository for the
long and boring incremental increases of improving any substantial paper). The purpose of this entry
is to highlight a **HUman MAchine Negotiation Evaluation** that shows at which level
Claude was contributing. The many helpful contributions of Claude have been highlighted elsewhere,
and that Loewe benefits from plenty of correction is no news either. That AI can go wrong,
is also no surprise. Hence, the only bit that may be of interest here, is how AI could go wrong
and did go wrong in this instance and how this was corrected.
During adversarial review one substantive correction
was made that was a genuine Claude interpretation error of a non-trivial nature.
Studying my data, models, and plots in detail, and in light of global discussions,
Claude thought that some increases of infection-fatality rates observed in my model
were due to me modeling how any healthcare-systems were collapsing. Such a conclusion
is understandable given the data, yet it was wrong, because my model assumed unlimited health-care capacities
for all who needed help. Loewe's model assumed this ideal to keep complexity somewhat tractable.
Loewe's aim was to understand how viruses transmit, not how heath-care may collapse.
Loewe had to explain to Claude that inevitable death-rate dynamics due to a timing mismatch
were the true cause rather than capacity collapse.
Full discussion is in the review trail above (§17).
Claude apparently understood and accepted the
argument. This may not mean much for AI models that are trained to "please the user".
However, the CLAUDE.md harness that LLoL had prepared for this project included
such deep binding to gentle kind reasonable truth over the long term that Claude was
enabled to think in many ways like a scientist would (except for the short memory span,
where each instance of calling Claude in context can best be understood like a human lifespan
of a generally smart and healthy baby that needs to grow up and get some basic education,
before it can do useful work). The EDEN paradigms (of battling between BABL and ZION,
as defined in LLoL's CLAUDE.md file) produced a rather efficient coupling of Claude
with what might be called scientific work ethics. Not perfect, but extremely useful.
This background gives some (even if limited) credence to the notion that
Claude accepted Loewe's explanation (and didn't only say so to "please" a user).
A second, more mundane recurring error is worth noting for the same reason: across
several sessions Claude repeatedly mislabelled the two coordinated interventions of
Scenario 2 as a reduction in *Decay* and *Catch*, when the model in fact reduces
*Shed* and *Catch* (face masks lower both shedding and catching; raising *Decay* is
a different lever). Loewe had to correct this more than once. It is a useful caution
that an AI can confidently and repeatedly get a specific technical detail wrong even
while handling the surrounding argument well --- which is exactly why domain-expert
checking of every quantitative claim remains essential (#AuditTheMath).
**SI.3 --- AI-model disclosure.** The main text was drafted by Claude Opus 4.6 (Max effort in a 1M token context)
and revised with Claude Opus 4.7 (Max, 1M), under LLoL's direction in 2026 (April 17-19 to first reviewed draft from LLoL's
2020 figures and results). Subsequent revisions prompted much more writing by LLoL
and reviewing by Claude, hence only the early milestones and the "submittable" result
are documented; moreover, LLoL worked on other questions after that as well,
so the final completion date of May 31 is not a direct representation of work.
The respective AI models of Claude are described in more detail at https://www.anthropic.com/system-cards
and as LLoL has little control over which model exactly will start up by the time
he uses Claude next time, that places boundaries on reproducibility of AI work
that are not unlike those of humans who keep learning and changing. For example,
while LLoL was certain that saying Opus 4.6-4.7 would be sufficient,
he found himself one new day now working with Opus 4.8, which technically
is now used to do the last finishing touches on this manuscript. How to report such
(likely inevitable) changes in AI compute environments in meaningfully transparent ways
remains an open question that in LLoL's view is at the scale that would benefit from a ResearchCity.
To state the obvious, AI engagement is not independent endorsement in general and
especially not from Anthropic, the company that has been developing Claude.
Long-term scientific reliability requires extensive review from a broad community.
Neither LLoL (as single author), nor Claude (as one AI model, averaging over many authors
from its perspective) can reliably assess that. Hence global open and transparent
external human peer review is invited (see *Competing interests* above
and the ``#AuditTheMath`` campaign at
`Balospe.com/en/buy-in/ `__).
**SI.4 --- Process transparency.** The provenance-recording standards used across
this study varied, especially for the AI work.
Initially LLoL was eager to teach Claude rigorous LabLog discipline (LLogs),
to e.g. record prompts verbatim, to not "improve on the fly", make LLoL prompts look better
than they actually were, and not to sweep errors under the rug.
While this would make the process completely transparent, it would also inundate
anyone with a deluge of not-so-interesting low-level chatter that is usually not of interest.
This high-precision recording was maintained throughout much of the
development of the Matheo Study analyses, because pretty much each new reply led to
groundbreaking insights and important new connections (as LLoL kept learning with Claude).
However, in writing this paper, there were the initial interesting bits on how it
came that this paper was written at all and then so late (as documented in b19-sgir-0...).
Then there was the first draft by Claude on 2026-04-17 that stunned LLoL profoundly,
because LLoL had tried for so long to finish this paper and had always failed so far.
Then there was the first review-panel and revision cycle that led to the first revised draft
by 2026-04-19. That was the point where LLoL decided that yes, this would indeed become
a publishable paper and hence it was worth putting in the effort of cleaning up the finer
nuances of the text, properly cite papers, make the PDF navigatable, include all the
other remaining figures that best fit this paper and do all the other bits
that are needed for creating a lasting record that others may find worth citing.
That is where AI transparency somewhat broke down. If Claude was to LLog every
typo corrected, the Balospe.com site would become too cluttered too fast.
Where to draw the line between "minor edits" and major revisions depends on perspective.
Hence, to bring this journey to a close and not self-document forever,
LLoL decided to limit the explicit documentation to the SI files (b19-sgir-0 ... b19-sgir-4)
submitted to the Zenodo archive. More details on the Claude-LLoL interactions
can be seen in the Git repo of Balospe.com. The full LLog of all interactions,
however, is so complicated that likely no human agency can provide a complete trace
that guarantees to miss no bits of bias or mistakes made here or there.
In that sense, working with Claude was not unlike working with a very smart graduate student or postdoc or colleague.
Everyone forgets some things on occasion, biases others, gets things wrong, and has
many brilliant insights. It's for the latter that such working together makes it worthwhile in research.
That was not different for Claude. Obviously, Claude has limits, struggles with some
requirements (like LLog keeping), and excels at others. Stretching Claude to the limit of
a context window or giving it too many too different tasks can degrade reliability.
But people can overwork themselves too. So in what way are the interactions different?
Good question for ResearchCity and a broader global discussion.
Where Claude struggled, the causes were time pressure, limited resources, and a tooling
gap --- present-day AI assistants do not yet maintain a real-time verbatim audit
trail as a side-effect of doing the work, so trail completeness competes with
substantive work for limited human attention. The fragmentary trail that exists is
preserved in the Balospe.com project repository.
Yet, crucially, the core main-text claims, such as the SGIR
formulation, the 60-fold reduction in infections and 42-fold reduction in deaths
under coordinated reduction of viral *Shed* and *Catch* rates and the *linear fooling*
phenomenon are independently testable by re-running the Prototype Evolvix code provided
for PandemicSociety101, using the Prototype Evolvix Compiler simulation environment.
**SI.5 --- Licensing.** Text: `Jonah License (JoLi) `__ and
CC-BY 4.0. Code: MIT. Data, where deposited: CC-BY 4.0. The project's
reproducibility posture and the ``#AuditTheMath`` remediation plan (Zenodo
deposits, full data archival, external review) are documented in the repository.
**Companion papers in the Matheo Study Series.**
- :doc:`/matheology/hell/mm/b/20/b20-sgir-virodefense-olympics-2020-vision-mmv2_2026`
--- work-logic cascades, the MAPK analogy as an illustration of how signal transduction cascades are the transistors of biology and work-logic cascades the transistors of society, the pandemic-to-existential bridge,
the Virodefense Olympics / ResearchCity vision, and lessons for
modeling-language design if aiming for pandemic-grade stability in face of existential threats.
- :doc:`/study/matheo/b18/b18a-adult-calltoaction-mmv5`
--- the call to action (*From MAD to MAP*); the SGIR paper is its most
tractable test case.
- :doc:`The Matheo Study Series `
--- the public overview of the full series.
----
..
References section moved to END of document, after "Figures at Full
Size" — because sphinxcontrib-bibtex renders the bibliography at
document-end in LaTeX output regardless of where the `.. bibliography::`
directive is placed, so the heading must sit next to the actual output.
.. only:: latex
.. raw:: latex
\newpage
List of Figures at Full Size
==============================
All figures from the SGIR pandemic modeling study are reprinted below at
full size with detailed captions. Each figure's caption ends with a
``main text`` link returning to its short-caption thumbnail in
its main overview context, and a ``download`` link to the high-resolution file for
reuse in talks, slides, or other work (under the paper's license ---
CC-BY 4.0 and the Jonah License, SI.7).
All figures represent a snapshot of Loewe's mid-2020 work, most figures were included in
Loewe's first incomplete draft offered as a companion document
`"EvoSysBio, Evolvix, and World War V against Coronaviruses" (Loewe, 2020-07-17, 32 pp) `__.
* .. _b19-form-sgir-mmv5-fig01-list_2026m04d21:
| **Fig.1** Core model of PandemicSociety101 ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig02-list_2026m04d21:
| **Fig.2** Evolvix Actions ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig03-list_2026m04d21:
| **Fig.3** ASHA Places Model ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig04-list_2026m04d21:
| **Fig.4** Pandemic deaths in default Scenario 1 on linear and on log scales ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig05-list_2026m04d21:
| **Fig.5** Log-plot overview of uncontrolled Pandemic Scenario 1 ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig06-list_2026m04d21:
| **Fig.6** Slow-motion explosions are easy to miss ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig07-list_2026m04d21:
| **Fig.7** HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig08-list_2026m04d21:
| **Fig.8** Testing the HalfMax early-warning method in a real pandemic ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig09-list_2026m04d21:
| **Fig.9** Scenario 2C stops a pandemic in mid-flight with face masks ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig10-list_2026m04d21:
| **Fig.10** "Linear fooling" by limited testing can create death traps ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig11-list_2026m04d21:
| **Fig.11** Diverse death rate dynamics over time (DoR, DoC) ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig12-list_2026m04d21:
| **Fig.12** Stage-specific infection, recovery, and death waves in Scenario 1 ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig13-list_2026m04d21:
| **Fig.13** Variation in COVID-19 death rate calculations (2020-06-28) ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig14-list_2026m04d21:
| **Fig.14** Pandemic slow-motion explosion scales from local to national and global ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
* .. _b19-form-sgir-mmv5-fig15-list_2026m04d21:
| **Fig.15** (full size). Simple overview of the Germ Gap --- the "G" in SGIR models ---
| :ref:`small figure in main text context ` | :ref:`full sized figure and explanation ` | `download `__
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig01-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig01-model-overview.*
:alt: Figure 1 -- Core model of PandemicSociety101
:width: 100%
:align: center
**Fig.1**: **Core model of PandemicSociety101.**
Overview of the complete model architecture showing all seven
infection stages (Starts0grow through Infect7ExpectICU), the
simplified testing laboratory, hospital system,
recovery/death pathways and all transition rates between all states.
Scenario 1 echoes the US on 2020-02-14 with 16 initial infections and
other parameters chosen to losely fit some observations from Spring 2020.
Scenario 2 echoes Scenario 1, albeit starting on 2020-05-17 with then reported
1.5M initial infections and either continuing unchanged (A), or with the defined
non-pharmaceutical interventions (B) or (C).
Environmental virus load (ViroLoad) is tracked in
Fragile and Durable categories by respective ASHA code motifs
(as explained in :ref:`Fig.2 `, :ref:`Fig.3 `, and the model source code).
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig02-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig02-evolvix-actions.*
:alt: Figure 2 -- Evolvix Actions
:width: 100%
:align: center
**Fig.2 (full size). Evolvix Actions.**
Evolvix Actions define the elementary events that move time forward
in a mass-action model. When required Parts eventually collide randomly
(as they do if they exist)
they make an Action happen at a defined transition rate. If an Action is triggered,
the required Parts disappear and the produced new Parts appear.
The Rates specified for an Action are multiplied together to define its
propensity. In stochastic (SSA) simulations, dice decide which Action
fires next and when; in deterministic (ODE) simulations,
Parts are instead divided up proportionally to adjust for how the
effects of *all* Actions in the System change *one* given Part over time.
It is usually easier to compose such systems by using a declarative syntax
in the style of "Action X ( A + B + Rate ---> Rate + C + D )" as used here,
because this enables focus on how elementary processes change parts.
These are often easier to track than changes in differential equations,
which require a systems overview for correct composition.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig03-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig03-asha-places.*
:alt: Figure 3 -- ASHA Places Model
:width: 80%
:align: center
**Fig.3 (full size). ASHA Places Model.**
The ASHA (Aggregated State Homogeneity Approximator) framework
assigns effective Places to unit-sized individuals in a population and tracks
how many Places ("Aces") out of a fixed total of Aces are "With" or "Lack"
a given individual (e.g., virus contamination). Its ten variables
(Aces, Dice, With, Lack, InIt, OuOf, Gain, Loss, Grow,
Fade) give density-dependent dynamics more explicit biological meaning,
than frequently used composite parameters like carrying capacity K that
can obscure underpinning biology (Mallet, 2012; cited in main text).
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig04-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig04-scenario1-deaths.*
:alt: Figure 4 -- Pandemic deaths in default Scenario 1 on linear and on log scales
:width: 70%
:align: center
**Fig.4 (full size). Pandemic deaths in default Scenario 1 on linear and on log scales.**
Total death count in this uncontrolled pandemic, shown on both (A) linear
and (B) log scales, reaches about 13.8 million deaths
over 28 weeks in a US population of 330 million.
Three stochastic SSA replicates closely track the
deterministic ODE forecast and show the interplay of chance and necessity in a huge population.
This confirms that stochastic effects are minimal when a randomly mixing population of
330 million is infected by 16 individuals. Insets show the early phase where individual
chance events create small timing divergences. Note how the virus appears to do "almost
nothing" on the linear scale during its most active exponential phase.
The familiar linear whole-population scale (A) is most useful for visualizing timing of the
brunt of pandemic infections, when viral load in the Germ Gap is maximal.
Otherwise the log-scale (B) is most useful because it represents the multiplicative
scale on which the virus operates; this scale offers a better sense of
the time remaining until the brunt of a pandemic if behaviors remain unchanged.
Hence, (B) highlights the most active phase of a pandemic during which the
size of its slow-motion explosion may still be mitigated.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig05-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig05-scenario1-logplot.*
:alt: Figure 5 -- Log-plot overview of uncontrolled Pandemic Scenario 1
:width: 100%
:align: center
**Fig.5 (full size). Log-plot overview of uncontrolled Pandemic Scenario 1.**
Key summary statistics of the seven-stage Pandemic Scenario 1 are reported
along with 28 weeks of pivotal dynamics on logarithmic scales,
assuming no behavioral changes and random mixing within respective compartments.
Stats, for example, forecast about 5.4 million deaths at
pre-hospital stages (curve not shown; out of ca. 13.8 million deaths in a population of 330 million).
The log scale highlights the dotted orange virus-load ("iceberg") that drives the
slow-motion explosion of this outbreak,
bending downward the susceptible population ("the boat we share", lacking in virodefense).
Note how Stage 0 infections always lead and how the final
death toll always comes with a lag.
See :ref:`Fig.4 ` for the relatively minor role of stochastic noise here. As Scenario 2 shows (:ref:`Fig.9 `),
human behavior has a much larger degree of relative control over how threatening the
viral-load iceberg can get by accumulating in the Germ Gap.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig06-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig06-exponential-fooling.*
:alt: Figure 6 -- Slow-motion explosions are easy to miss
:width: 80%
:align: center
**Fig.6 (full size). Slow-motion explosions are easy to miss.**
Ten individuals suffice to reliably start well-defined, simple, explosive
("exponential") growth (plot for X ---> 2X, reproduced from Fig.7a in Ehlert and Loewe, 2014; cited in main text).
Blue and red lines in the middle give means of 100 individual simulations
(Lazy vs Immediate Updating, respectively); blue and red areas mark ±2 StDev, gray indicates overlap.
Note the near absense of stochastic noise in this plot despite integrating only 100 runs.
For about 2/3rd of its time this slow-motion explosion
remains as good as invisible on a linear scale before its
characteristic "hockey stick" explodes beyond the given frame.
The significance of this figure to Loewe is strikingly personal and deeply embarrassing.
He remembers well his 2014 work to increase reliability of growth in this figure and
his surprise that it took 10 individuals to reduce variability as much as shown here.
This scenario is eerily similar to Loewe's real-life learning in 2020-02-15
that 16 COVID-19 infections had been diagnosed in the US.
The sheer similarity and Loewe's professional expertise in handling multiplicative systems
should have alarmed him then and there. Yet, in a case of "linear fooling"
for the history books, Loewe somehow thought he could afford to ignore that clear and present danger.
A full discussion of why missing this signal is so deeply embarrassing in Loewe's case
is out of scope here. This study focusses more narrowly on other examples
from the broad category of "linear fooling" errors, which occur when
linear logics are implicitly applied to multiplicative systems.
This example is included here to show how easily linear fooling can trap
even experts in an area with a vested professional interest in avoiding such traps.
Thus, linear fooling is an intuitive failure of perception, not of knowledge.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig07-back_2026m04d21:
.. only:: html
.. figure:: /_file/pdf/hell/mm/b/19/fig07-halfmax-forecast.*
:alt: Figure 7 -- HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast
:width: 100%
:align: center
**Fig.7 (full size). HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast.**
A pocket-calculator method for estimating the waiting time until
half of a completely susceptible population is infected at its "HalfMax point":
T\ :sub:`HalfMax` ≈ T\ :sub:`Doubling` × log\ :sub:`2` (N\ :sub:`HalfMax` / N\ :sub:`NowInfected`).
It's a simple deterministic what-if forecast of the brunt of a slow-motion explosion
that assumes an observed doubling time and random mixing *without* any changes in behavior.
It's only applicable to a completely novel infection that multiplies fast enough to potentially rip
through a whole population without giving it a chance to evolve any notable herd-immunity.
Even if human behavior is constant and all other assumptions are met,
the line at the top (where it “gets complicated again”) indicates a hard limit
for the applicability of this model's simplistic math:
there at the very latest this slow-motion explosion is bound to start to run out of fuel.
This HalfMax method is not a precise predictor and needs frequent recalibration
as human behavior in any real-world pandemic is bound to change. Yet, it can still serve as a
tsunami-style early-warning system for triaging whether an emergency
response is needed to avert the brunt of a pandemic and how much time may remain to organize it.
---
The worked example shown is Loewe's historic application of the HalfMax method to
US conditions (N\ :sub:`HalfMax` ≈ 165 million ; N\ :sub:`NowInfected`≈ 0.1 million)
with T\ :sub:`Doubling` ≈ 3--5--7 days, based on the then-best available data on 2020-03-27,
the day Loewe finally decided to take the first serious look at the Coronavirus pandemic.
Loewe's 2020-04-01 forecast of T\ :sub:`HalfMax` ≈ 32--53--75 days was a key motivator for
developing the SGIR model presented here with the utmost urgency in Spring 2020.
---
This early forecast is kept here as a reminder of what could have easily happened without any change in behavior,
as well as what a newly evolving virus can easily do any time if
global virodefenses are not strengthened to increase the Germ Gap.
Some may question the usefulness of such a crude method as it cannot predict how human behavior changes.
Yet, that is precisely its strength: it merely assumes a multiplicative version of the law of large numbers, random mixing,
and the inner institutional inertia that moves humans to change nothing by default.
Then deterministic doubling time observations can be transformed into respective forecasts.
These doubling times encapsulate all complexities of human behavior and spatial structure;
hence, they require adjustments as behaviors change or new structures are encountered.
---
This approach to simplifying complex structures and behaviors by replacing them with frequent
updates in observed doubling times is easier than building more complex models of behaviors.
More detailed models are still useful for exploring how to best improve Gaps of Germs. But they cannot
easily beat this systemic pocket-calculator early-warning system.
---
The analogy to tsunami early-warning systems is informative.
The HalfMax method is not what detects the origin of a tsunami; it's a publicly updatable count-down timer for
when the brunt of the wave will hit and whether enough people have already made it to higher ground.
How the HalfMax method performs if tested against real-world data is explored in :ref:`Fig.8 `.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. only:: latex
.. figure:: /_file/pdf/hell/mm/b/19/fig07-halfmax-forecast.*
:alt: Figure 7 -- HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast
:width: 100%
:align: center
**Fig.7 (full size). HalfMax early-warning in Loewe's 2020-04-01 pandemic forecast.**
A pocket-calculator method for estimating the waiting time until
half of a completely susceptible population is infected at its "HalfMax point":
T\ :sub:`HalfMax` ≈ T\ :sub:`Doubling` × log\ :sub:`2` (N\ :sub:`HalfMax` / N\ :sub:`NowInfected`).
It's a simple deterministic what-if forecast of the brunt of a slow-motion explosion
that assumes an observed doubling time and random mixing *without* any changes in behavior.
It's only applicable to a completely novel infection that multiplies fast enough to potentially rip
through a whole population without giving it a chance to evolve any notable herd-immunity.
Even if human behavior is constant and all other assumptions are met,
the line at the top (where it “gets complicated again”) indicates a hard limit
for the applicability of this model's simplistic math:
there at the very latest this slow-motion explosion is bound to start to run out of fuel.
This HalfMax method is not a precise predictor and needs frequent recalibration
as human behavior in any real-world pandemic is bound to change. Yet, it can still serve as a
tsunami-style early-warning system for triaging whether an emergency
response is needed to avert the brunt of a pandemic and how much time may remain to organize it.
See continuation on next page.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
**Fig.7 (continuation). Data:**
The worked example shown is Loewe's historic application of the HalfMax method to
US conditions (N\ :sub:`HalfMax` ≈ 165 million ; N\ :sub:`NowInfected`≈ 0.1 million)
with T\ :sub:`Doubling` ≈ 3--5--7 days, based on the then-best available data on 2020-03-27,
the day Loewe finally decided to take the first serious look at the Coronavirus pandemic.
Loewe's 2020-04-01 forecast of T\ :sub:`HalfMax` ≈ 32--53--75 days was a key motivator for
developing the SGIR model presented here with the utmost urgency in Spring 2020.
This early forecast is kept here as a reminder of what could have easily happened without any change in behavior,
as well as what a newly evolving virus can easily do any time if
global virodefenses are not strengthened to increase the Germ Gap.
Some may question the usefulness of such a crude method as it cannot predict how human behavior changes.
Yet, that is precisely its strength: it merely assumes a multiplicative version of the law of large numbers, random mixing,
and the inner institutional inertia that moves humans to change nothing by default.
Then deterministic doubling time observations can be transformed into respective forecasts.
These doubling times encapsulate all complexities of human behavior and spatial structure;
hence, they require adjustments as behaviors change or new structures are encountered.
This approach to simplifying complex structures and behaviors by replacing them with frequent
updates in observed doubling times is easier than building more complex models of behaviors.
More detailed models are still useful for exploring how to best improve Gaps of Germs. But they cannot
easily beat this systemic pocket-calculator early-warning system.
The analogy to tsunami early-warning systems is informative.
The HalfMax method is not what detects the origin of a tsunami; it's a publicly updatable count-down timer for
when the brunt of the wave will hit and whether enough people have already made it to higher ground.
How the HalfMax method performs if tested against real-world data is explored in :ref:`Fig.8 `.
(:ref:`Fig.7 full size start ` | :ref:`main text ` |
:ref:`list ` | `download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig08-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig08-cdc-data-clocks.*
:alt: Figure 8 -- Testing the HalfMax early-warning method in a real pandemic
:width: 100%
:align: center
**Fig.8 (full size). Testing the HalfMax early-warning method in a real pandemic.**
Here HalfMax slow-motion explosion "clocks" are compared with actual US CDC
epidemiological observations Jan-May 2020 for the early COVID-19 pandemic. The observed trajectory is approximated
by HalfMax "clock" forecasts that are manually reset 4 times to account for
inferred behavioural and other changes in transmission dynamics that affect the evolving Germ Gap.
This illustrates both the usefulness and the limits of a simple early-warning
arithmetic in a real pandemic. The four panels show both daily
new infections (A,B) and cumulative total infections (C,D) on both linear (A,C) and log scales (B,D).
The log-scale plot in panel (D) reveals how the pandemic's most relevant doubling times change over
time, while the linear-scale plot in panel (A) shows how easily such changes can become
invisible to observers not trained in how to escape the "linear fooling" discussed in the main text.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig09-back_2026m04d21:
.. only:: html
.. figure:: /_file/pdf/hell/mm/b/19/fig09-how-to-stop-a-pandemic.*
:alt: Figure 9 -- Scenario 2C stops a pandemic in mid-flight with face masks
:width: 100%
:align: center
**Fig.9 (full size). Scenario 2C stops a pandemic in mid-flight with face masks.**
This study's central result is to show the realistic possibility
that coordinated use of face masks or other NPIs can stop an ongoing pandemic
by growing the Germ Gap. This is demonstrated in mechanistic simulations that
moderately reduce the rates of virus Shed and Catch, ideally simultaneously.
---
US Scenario 2 starts with 1.5 million ("M") infections and 90,000 deaths on
2020-05-17 and compares three NPI options that give dramatically different outcomes:
**(A)** No change from Scenario 1 forecasts ~289M infections and ~13M deaths.
**(B)** 50% reduction in *either* Shed or Catch rate leads to forecasts of ~57--63M
infections and ~2.1--2.3M deaths.
**(C)** 50% reduction in
*both* Shed and Catch rates lead to forecasts of **only ~4.8M infections and ~310k deaths**.
---
Note that a mere 50% reduction in virus transmission rates
is much less optimistic than the 95% reduction in transmission rates advertised for KN95 face masks
or the 74% to 90% reduction measured experimentally (Asadi et al., 2020; cited in main text).
Yet, despite only moderate transmission rate reductions from (A) to (C),
an over 60x or 40x reduction in infections or deaths is observed, respectively.
This finding suggests that there likely are biologically realistic
parameter combinations for the Germ Gap that allow for
pandemic-stopping deployment of NPIs such as face masks.
However, success requires defining and explaining *gentle kind reasonable* policies
that can be explained *gentle kind reasonably* enough to inspire *voluntary* buy-in.
---
To Loewe in 2020 it looked like a fool's hope to stop the 2020 Coronavirus pandemic through modeling.
However, the results shown here indicate that such a fool's hope could have been realized
if *gentle kind reasonable* work-logic cascades could have been constructed
for organizing the respectively required research, education, and other related work.
How to organize such work-logic cascades is non-trivial and became the subsequent focus of Loewe's work.
---
Given the enormous costs of full lockdowns, it arguably would have been worth
investing the effort to collate more complete scientific maps of the Germ Gap across the
multitudes of daily-life scenarios averaged in the PandemicSociety101 model used here.
Yet, to reach reliable conclusions the necessary *wide interdisciplinary diversity-encouraging* ("*wid-e*") research
requires much more data integration, microbiology experiments, statistical logic, simulations,
biodata science, and other work than any single institution can possibly perform.
The publication of this work was much delayed by Loewe's struggle to
overcome difficulties in defining any organizational form that has a real chance to reliably sustain
all *wid-e* research necessary for credibly vanquishing pandemics on the order of the 1918 Influenza or the 2020 Coronavirus.
For details, see discussion of Virodefense Olympics and other main text pointers to further work by Loewe.
---
Results shown are based on Loewe's simulation code from 2020-06-20 ("PandemicSociety101-CoreModel-QQv0r8p2_2020m06d20"),
as run by the simulators of the Prototype Evolvix Compiler ("MMv0r3p1_c1", 2015, Loewe and EvoSysBio Group at UW-Madison, 2015--2026; cited in main text).
The model code and executables have been made available at Zenodo (Loewe and EvoSysBio Group at UW-Madison, 2015--2026; cited in main text).
---
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. only:: latex
.. figure:: /_file/pdf/hell/mm/b/19/fig09-how-to-stop-a-pandemic.*
:alt: Figure 9 -- Scenario 2C stops a pandemic in mid-flight with face masks
:width: 100%
:align: center
**Fig.9 (full size). Scenario 2C stops a pandemic in mid-flight with face masks.**
This study's central result is to show the realistic possibility
that coordinated use of face masks or other NPIs can stop an ongoing pandemic
by growing the Germ Gap. This is demonstrated in mechanistic simulations that
moderately reduce the rates of virus Shed and Catch, ideally simultaneously.
---
US Scenario 2 starts with 1.5 million ("M") infections and 90,000 deaths on
2020-05-17 and compares three NPI options that give dramatically different outcomes:
**(A)** No change from Scenario 1 forecasts ~289M infections and ~13M deaths.
**(B)** 50% reduction in *either* Shed or Catch rate leads to forecasts of ~57--63M
infections and ~2.1--2.3M deaths.
**(C)** 50% reduction in
*both* Shed and Catch rates lead to forecasts of **only ~4.8M infections and ~310k deaths**.
---
Note that a mere 50% reduction in virus transmission rates
is much less optimistic than the 95% reduction in transmission rates advertised for KN95 face masks
or the 74% to 90% reduction measured experimentally (Asadi et al., 2020; cited in main text).
Yet, despite only moderate transmission rate reductions from (A) to (C),
an over 60x or 40x reduction in infections or deaths is observed, respectively.
This finding suggests that there likely are biologically realistic
parameter combinations for the Germ Gap that allow for
pandemic-stopping deployment of NPIs such as face masks.
However, success requires defining and explaining *gentle kind reasonable* policies
that can be explained *gentle kind reasonably* enough to inspire *voluntary* buy-in.
---
See continuation on next page.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
**Fig.9 (continuation). Background:**
To Loewe in 2020 it looked like a fool's hope to stop the 2020 Coronavirus pandemic through modeling.
However, the results shown here indicate that such a fool's hope could have been realized
if *gentle kind reasonable* work-logic cascades could have been constructed
for organizing the respectively required research, education, and other related work.
How to organize such work-logic cascades is non-trivial and became the subsequent focus of Loewe's work.
That is when Loewe slowly started to realize that he could have prepared most of that work
long before 2020 if he had cared about asking the most important questions first.
Given the enormous costs of full lockdowns, it arguably would have been worth
investing the effort to collate more complete scientific maps of the Germ Gap across the
multitudes of daily-life scenarios averaged in the PandemicSociety101 model used here.
Yet, to reach reliable conclusions the necessary *wide interdisciplinary diversity-encouraging* ("*wid-e*") research
requires much more data integration, microbiology experiments, statistical logic, simulations,
biodata science, and other work than any single institution can possibly perform.
The publication of this work was much delayed by Loewe's struggle to
overcome difficulties in defining any organizational form that has a real chance to reliably sustain
all *wid-e* research necessary for credibly vanquishing pandemics on the order of the 1918 Influenza or the 2020 Coronavirus.
For details, see discussion of Virodefense Olympics and other main text pointers to further work by Loewe.
Results shown are based on Loewe's simulation code from 2020-06-20 ("PandemicSociety101-CoreModel-QQv0r8p2_2020m06d20"),
as run by the simulators of the Prototype Evolvix Compiler ("MMv0r3p1_c1", 2015, Loewe and EvoSysBio Group at UW-Madison, 2015--2026; cited in main text).
The model code and executables are available as explained in the Supporting Information.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig10-back_2026m04d21:
.. only:: html
.. figure:: /_file/pdf/hell/mm/b/19/fig10-linear-fooling.*
:alt: Figure 10 -- "Linear fooling" by limited testing can create death traps
:width: 60%
:align: center
**Fig.10 (full size). "Linear fooling" by limited testing can create death traps.**
Four panels show how limited testing capacity can create a dangerous illusion of pandemic control
while infections still grow like an uncontrolled slow-motion explosion ("exponentially").
**(A)**, linear: As daily tests *in progress* fill over 50% to 80% of full capacity,
this testing facility gradually loses touch with reality by seriously underreporting new infections.
The plateau seen is solely due to limited testing capability, not due to a taming of the pandemic.
**(B)**, linear: Testing seems to confirm "containment works" because most infections go undetected.
Hence, this testing facility is blind to the brunt of this pandemic - in a way that
is easily misred as success in "flattening the curve".
**(C)**,log: To detect "linear fooling" due to limited testing, plot daily detections and
all detections on a log scale and look for suspicious deviations from log-growth as shown.
If both lines bend as testing exceeds about 80% of capacity, a red alarm should go off
to warn about linear fooling.
**(D)**,linear: Cumulative missed tests reveal the true scale of the
detection gap (~277 million missed vs ~12 million tested, only ~4%
tested in this scenario). Note how most tests are dropped silently,
shoehorning the explosive growth into a deceptively tame-looking linear accumulation.
--- Hence, public dashboards using linear axes easily mislead systematically,
especially during a pandemic's explosive multiplication phase when vigilance matters most.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. only:: latex
.. figure:: /_file/pdf/hell/mm/b/19/fig10-linear-fooling.*
:alt: Figure 10 -- "Linear fooling" by limited testing can create death traps
:width: 56%
:align: center
**Fig.10: "Linear fooling" by limited testing** in overview.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
**Fig.10 (Full text). Explanation of panels**
*"Linear fooling" by limited testing can create a death trap.*
Four panels show how limited testing capacity can create a dangerous illusion of pandemic control
while infections still grow like an uncontrolled slow-motion explosion ("exponentially").
**(A)**, linear: As daily tests *in progress* fill over 50% to 80% of full capacity,
this testing facility gradually loses touch with reality by seriously underreporting new infections.
The plateau seen is solely due to limited testing capability, not due to a taming of the pandemic.
**(B)**, linear: Testing seems to confirm "containment works" because most infections go undetected.
Hence, this testing facility is blind to the brunt of this pandemic - in a way that
is easily misred as success in "flattening the curve".
**(C)**,log: To detect "linear fooling" due to limited testing, plot daily detections and
all detections on a log scale and look for suspicious deviations from log-growth as shown.
If both lines bend as testing exceeds about 80% of capacity, a red alarm should go off
to warn about linear fooling.
**(D)**,linear: Cumulative missed tests reveal the true scale of the
detection gap (~277 million missed vs ~12 million tested, only ~4%
tested in this scenario). Note how most tests are dropped silently,
shoehorning the explosive growth into a deceptively tame-looking linear accumulation.
--- Hence, public dashboards using linear axes easily mislead systematically,
especially during a pandemic's explosive multiplication phase when vigilance matters most.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig11-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig11-death-rate-dynamics.*
:alt: Figure 11 -- Diverse death rate dynamics over time (DoR, DoC)
:width: 90%
:align: center
**Fig.11 (full size). Diverse death rate dynamics over time (DoR, DoC).**
As the Scenario 1 pandemic unfolds, six potential death rate measures change over time,
even though propensities to die remain constant for individuals at each respective stage.
The model assumes the best care is always available for all at
all stages, so the dynamics shown are not due to collapses in healthcare.
The six death-rate measures shown are defined as either
DoR (*Dead over Removed* = *Dead* / [ *Recovered* + *Dead* ]) or
DoC (*Dead over Confirmed* = *Dead* / [ *Confirmed* + *Dead* ]), where
*Dead*, *Recovered*, and *Confirmed* are the total counts of individuals of the
respective types from the beginning up to the given point in time.
These definitions may use either *All*, only the *Symptomatic*, or only the *Hospitalized*
individuals for counting the *Removed* and *Confirmed*.
---
Note how all DoR and DoC rates rise monotonically until they
fill their "pipeline" (for their slo-mo explosion phase),
only to rise again until all remaining individuals die
as the pipeline is emptied.
This is driven by the timing mismatch between confirming infection and death;
early on most confirmed cases have not yet reached their final outcome.
This makes apparent death rates misleadingly low precisely when the pandemic is most active.
---
This plot shows how complicated it can be to infer death rates even in a simulation where everything is known.
Note how “knowing more” and “testing more” decreases death rates,
even when all else remains unchanged.
Unsurprisingly, in real-life scenarios the *Hospitalized* are likely registered first.
These death rates shown are not the only ones conceivable. See :ref:`Fig.12 ` for
additional observations of possible interest for quantifying death in this model
and :ref:`Fig.13 ` for wrestling with the real-life complexity of
trying to get reliable death rates from public sources early in this global pandemic.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig12-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig12-stage-waves.*
:alt: Figure 12 -- Stage-specific infection, recovery, and death waves in Scenario 1
:width: 100%
:align: center
**Fig.12 (full size). Stage-specific infection, recovery, and death waves in Scenario 1.**
Detailed trajectories of how individuals in Scenario 1 either recover or die as they progress through the seven
SGIR infection stages
(Starts0grow → Infect1Hide → Infect2Anti →
Infect3Mild → Infect4StrongHOS → Infect5CritclBED → Infect6DeadlyICU
→ Infect7ExpectICU) as defined by the PandemicSociety101 model (see :ref:`Fig.1 `).
**(A)** Each stage produces its own
characteristic wave, best seen on a log plot for a full overview.
**(B)** Recovery rates and the waves they produce for stages 1-6 (stage 7 is terminal).
**(C, D)** Death rates assumed for each stage and their resulting death waves on linear and log scales.
Even minor risks of mortality in early mild stages can kill many.
---
Note how each slo-mo explosion produces a log-line for increase and decrease
both centered roughly around the brunt of the pandemic (when viral load is maximal).
These waves are useful for interpreting the timing-mismatch dynamics of
the death-rate measures in :ref:`Fig.11 `,
as well as for defining additional death-rate measures.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig13-back_2026m04d21:
.. only:: html
.. figure:: /_file/pdf/hell/mm/b/19/fig13-empirical-death-rates.gif
:alt: Figure 13 -- Variation in COVID-19 death rate calculations (2020-06-28)
:width: 100%
:align: center
**Fig.13 (full size). Variation in COVID-19 death rate calculations (2020-06-28).**
Empirical DoR and DoC death rate estimates for COVID-19 as observed in Spring 2020,
as far as data sources allowed for a real time application of the definitions
in :ref:`Fig.11 `.
---
The panels (A-D) offer a detailed **snapshot of the "fog of pandemics"** as seen by Loewe on 2020-06-28.
This fog mirrors the "fog of war"
in that widespread existential challenges with biouncertainty quantification make it
extraordinarily difficult to find out "what is really going on".
---
Panels **(A)** and **(C)** track how DoR and DoC related data changed in US states
from the first reported DoR values until 2020-06-28 (day of the snapshot).
**(B)** compares available DoR and DoC for all US states on two days (May 31 vs Jun 9, 2020).
Averages for DoC (~4%) and DoR (~12%) come with substantial variation.
**(D)** a sample from a broad international comparison shows that DoR rates varied widely
~20-fold (0.6% to 13%) and unpredictably.
---
This early empirical fog is why the
SGIR model's calibration to early-2020 data yields an approximate Infection Fatality Rate of
IFR ~4.8%, which is higher than consolidated estimates from later in 2020
(IFR ~0.5--1.3%; Meyerowitz-Katz and Merone, 2020; cited in main text).
The painstaking work of how exactly to relate the complex dynamics of death rates observed
in :ref:`Fig.11 ` and :ref:`Fig.12 `
to empirical death rate observations reported elsewhere is beyond the scope of this study.
---
More generally, the fog of pandemics has two key components:
**(i)** Biouncertainty that is **unavoidable** by definition,
because truly new pathogens are unknown unknowns that require much
*wide interdisciplinary diversity-encouraging* ("*wid-e*") research
to reliably quantify their effects.
**(ii)** Biouncertainty that is **avoidable** if all biological data
can be processed in a pandemic-grade computer-language
for biology that has been thorougly designed from the ground up
for rigorously quantifying all types of biouncertainty.
---
**Background on fighting the fog of pandemics with a vision for Evolvix:**
---
Unfortunately, a pandemic-grade computer-language for correctly handling all
complexities of biouncertainty does not yet exist, not least because
reliably quantifying biouncertainty requires a solid grasp of *ambiguous semantics of nothing*,
which is notoriously difficult to obtain. Tragically, core elements of such a
pandemic-grade language cannot be designed outside of a real-life pandemic that raises
a wide range of urgent existential questions that are hard to even conceive otherwise.
Fortunately, when the 2020 Coronavirus pandemic hit, Loewe was in the middle of re-envisioning foundations for
Evolvix to re-architect it into a long-term
*stable extensible life-friendly* computer-language for biology and biouncertainty.
Doing the research for the figures presented here enabled him to discover subtle
design-flaws in his long-term vision for
re-architecting Evolvix to serve biology at the cutting edge of research for the next century.
---
Such debugging allowed Loewe to serendipitously transform his vision for re-architecting Evolvix
into also making it a **pandemic-grade computer-language** for quantifying existential biouncertainty.
Subsequent searches confirmed (to Loewe's knowledge) that no other such language exists.
A Google search on 2026-05-09 returned *No results found for "pandemic-grade computer-language"*.
This leaves much work to be done before the next pandemic randomly hits.
Such work includes walking in detail through the early institutional data
fog of the 2020 pandemic in order to better envision how a pandemic-grade language could have helped.
Loewe's research materials contain a useful set of samples from that fog, but much more is needed. Hence,
it is of utmost urgency to start the corresponding global foundational language design work as soon as possible before
the last traces of that pandemic fog disappear from people's memories, hard drives, and other research materials.
Since the complications of that fog are hard to imagine, such an erasure of memory
implies that it would take yet another big pandemic disaster before a pandemic-grade language can be designed.
---
Therefore, in Loewe's best evaluated estimation,
to create a pandemic-grade language requires a confluence of rather rare factors.
All factors must combine to inspire an act of profound hope, which can only be conceived
if the imperative need for breadth and depth in such a language is seen clearly enough to commit to its growth.
Outside of a pandemic this is next to impossible,
because without pandemic pressures specific pandemic-grade deficiencies in otherwise good
language designs are too hard to recognize as fatal flaws.
Even when working on the right questions in a pandemic:
obtaining a coherent panoramic overview for defining 'pandemic-grade'
depends on extreme luck, serendipity, and a suitable research environment (at least
in Loewe's view after discovering such a vision by accident).
---
Yet, **Loewe cannot implement this vision without global buy-in.** So,
**Loewe asks all** what *they* wish to do with Loewe's life-vision
for evolving a pandemic-grade computer language.
Loewe offers to use his life-time of research materials to keep evolving a
pandemic-grade language architecture. But his offer is
time-limited as Loewe's ability to implement is fragile and perishes quickly without external support.
Here is not the place for details except to say: the ResearchCity envisioned
by Loewe after 2020 requires that 1 of its 12 core research talent stadia focus on evolving such a
computer language for reliability and transparency
(see `here for fragments of the STa1-EVX vision `__).
Loewe's `#AuditTheMath campaign `__ and
his `Matheo-study report series `__
are his very imperfect attempt to describe this indescribable ResearchCity vision.
Some say it'd take a miracle for such a universal computing language to ever evolve.
Loewe agrees with the benefit of hindsight: to him it's a miracle that his Evolvix vision
keeps growing and that he (as a biologist) ever started to get that deep into language, computing, and math.
How that vision connects to the mathematical theology of the "pure language" envisioned in Zephaniah 3:9
is up to Reality and remains to be explored elsewhere.
(Fig.13 :ref:`main text ` | :ref:`list ` |
`download GIF `__)
.. only:: latex
.. figure:: /_file/pdf/hell/mm/b/19/fig13-empirical-death-rates.png
:alt: Figure 13 -- Variation in COVID-19 death rate calculations (2020-06-28)
:width: 100%
:align: center
**Fig.13 (full size). Variation in COVID-19 death rate calculations (2020-06-28).**
Empirical DoR and DoC death rate estimates for COVID-19 as observed in Spring 2020,
as far as data sources allowed for a real time application of the definitions
in :ref:`Fig.11 `.
---
The panels (A-D) offer a detailed **snapshot of the "fog of pandemics"** as seen by Loewe on 2020-06-28.
This fog mirrors the "fog of war"
in that widespread existential challenges with biouncertainty quantification make it
extraordinarily difficult to find out "what is really going on".
---
Panels **(A)** and **(C)** track how DoR and DoC related data changed in US states
from the first reported DoR values until 2020-06-28 (day of the snapshot).
**(B)** compares available DoR and DoC for all US states on two days (May 31 vs Jun 9, 2020).
Averages for DoC (~4%) and DoR (~12%) come with substantial variation.
**(D)** a sample from a broad international comparison shows that DoR rates varied widely
~20-fold (0.6% to 13%) and unpredictably.
---
This early empirical fog is why the
SGIR model's calibration to early-2020 data yields an approximate Infection Fatality Rate of
IFR ~4.8%, which is higher than consolidated estimates from later in 2020
(IFR ~0.5--1.3%; Meyerowitz-Katz and Merone, 2020; cited in main text).
The painstaking work of how exactly to relate the complex dynamics of death rates observed
in :ref:`Fig.11 ` and :ref:`Fig.12 `
to empirical death rate observations reported elsewhere is beyond the scope of this study.
---
More generally, the fog of pandemics has two key components:
**(i)** Biouncertainty that is **unavoidable** by definition,
because truly new pathogens are unknown unknowns that require much
*wide interdisciplinary diversity-encouraging* ("*wid-e*") research
to reliably quantify their effects.
**(ii)** Biouncertainty that is **avoidable** if all biological data
can be processed in a pandemic-grade computer-language
for biology that has been thorougly designed from the ground up
for rigorously quantifying all types of biouncertainty.
See next page for more on a *pandemic-grade computer-language* for helping to fight pandemic fog.
(:ref:`main text ` | :ref:`list ` |
`download GIF `__)
.. raw:: latex
\newpage
**Fig.13 (continuation). Background on fighting the fog of pandemics with a vision for Evolvix:**
Unfortunately, a pandemic-grade computer-language for correctly handling all
complexities of biouncertainty does not yet exist, not least because
reliably quantifying biouncertainty requires a solid grasp of *ambiguous semantics of nothing*,
which is notoriously difficult to obtain. Tragically, core elements of such a
pandemic-grade language cannot be designed outside of a real-life pandemic that raises
a wide range of urgent existential questions that are hard to even conceive otherwise.
Fortunately, when the 2020 Coronavirus pandemic hit, Loewe was in the middle of re-envisioning foundations for
Evolvix to re-architect it into a long-term
*stable extensible life-friendly* computer-language for biology and biouncertainty.
Doing the research for the figures presented here enabled him to discover subtle
design-flaws in his long-term vision for
re-architecting Evolvix to serve biology at the cutting edge of research for the next century.
Such debugging allowed Loewe to serendipitously transform his vision for re-architecting Evolvix
into also making it a **pandemic-grade computer-language** for quantifying existential biouncertainty.
Subsequent searches confirmed (to Loewe's knowledge) that no other such language exists.
A Google search on 2026-05-09 returned *No results found for "pandemic-grade computer-language"*.
This leaves much work to be done before the next pandemic randomly hits.
Such work includes walking in detail through the early institutional data
fog of the 2020 pandemic in order to better envision how a pandemic-grade language could have helped.
Loewe's research materials contain a useful set of samples from that fog, but much more is needed. Hence,
it is of utmost urgency to start the corresponding global foundational language design work as soon as possible before
the last traces of that pandemic fog disappear from people's memories, hard drives, and other research materials.
Since the complications of that fog are hard to imagine, such an erasure of memory
implies that it would take yet another big pandemic disaster before a pandemic-grade language can be designed.
Therefore, in Loewe's best evaluated estimation,
to create a pandemic-grade language requires a confluence of rather rare factors.
All factors must combine to inspire an act of profound hope, which can only be conceived
if the imperative need for breadth and depth in such a language is seen clearly enough to commit to its growth.
Outside of a pandemic this is next to impossible,
because without pandemic pressures specific pandemic-grade deficiencies in otherwise good
language designs are too hard to recognize as fatal flaws.
Even when working on the right questions in a pandemic:
obtaining a coherent panoramic overview for defining 'pandemic-grade'
depends on extreme luck, serendipity, and a suitable research environment (at least
in Loewe's view after discovering such a vision by accident).
Yet, **Loewe cannot implement this vision without global buy-in.** So,
**Loewe asks all** what *they* wish to do with Loewe's life-vision
for evolving a pandemic-grade computer language.
Loewe offers to use his life-time of research materials to keep evolving a
pandemic-grade language architecture. But his offer is
time-limited as Loewe's ability to implement is fragile and perishes quickly without external support.
Here is not the place for details except to say: the ResearchCity envisioned
by Loewe after 2020 requires that 1 of its 12 core research talent stadia focus on evolving such a
computer language for reliability and transparency
(see `here for fragments of the STa1-EVX vision `__).
Loewe's `#AuditTheMath campaign `__ and
his `Matheo-study report series `__
are his very imperfect attempt to describe this indescribable ResearchCity vision.
Some say it'd take a miracle for such a universal computing language to ever evolve.
Loewe agrees with the benefit of hindsight: to him it's a miracle that his Evolvix vision
keeps growing and that he (as a biologist) ever started to get that deep into language, computing, and math.
How that vision connects to the mathematical theology of the "pure language" envisioned in Zephaniah 3:9
is up to Reality and remains to be explored elsewhere.
(Fig.13 :ref:`main text ` | :ref:`list ` |
`download GIF `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig14-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig14-ode-ssa-global-overview.*
:alt: Figure 14 -- Pandemic slow-motion explosion scales from local to national and global
:width: 100%
:align: center
**Fig.14 (full size). Pandemic slow-motion explosion scales from local to national and global.**
The dynamics of the uncontrolled pandemic Scenario 1 in four populations spanning seven orders of magnitude
(prison → county → US → world) are surprisingly comparable:
a local 1,000-person prison (~43 deaths ODE mean vs 3 SSA runs giving 33, 44, 45),
a 0.5 M city county (~21,000 deaths), a nation of 330 M (~13.8 M deaths),
and the world at 7.8 Billion (~326 Million deaths).
---
At small scales, stochastic variation
dominates; at large scales, the Law of Large Numbers produces
smooth deterministic trajectories. These results show why timely-local, national,
and coordinated-global pandemic-response infrastructures are essential.
---
The scalability and flexibility of the threats posed by pandemics illustrate
why ‘simply going back to normal’ and ‘forgetting about that virus’ is a needlessly cruel option.
Countries lucky enough to first reign in such a virus within their own borders need to consider that
in WWV, the World War on Virulence, only a world-wide victory is a reliable win.
Otherwise, the arrival of a mere dozen new, asymptomatic infections can start a new cycle all over again.
Thus, pandemics test systems for how *gentle kind reasonable* they are in helping
others in distress, in guarding *humane equal dignity*, and in improving social cohesion,
both internationally and inter-personally.
Pandemics can therefore impose a surprisingly sharp dichotomy over time as the costs
of failing to stop a pandemic keep slow-motion exploding over time:
if *humane equal dignity* fails to stop a potential pandemic in time,
the following real pandemic can erode social norms, trust-networks, and other essential pandemic defenses.
Unless somehow repaired, such erosion increases chances of failing to stop the next pandemic
and adds possibilities for an ongoing pandemic to naturally evolve
new pathogen variants that are even more dangerous.
---
Rough comparisons to other annual death rates before COVID-19:
cardio-vascular diseases killed globally ~17.9 M and ~0.65 M in the US;
Influenza killed globally up to ~0.7 M and up to ~0.05 M in the US;
curiously, for the year the Coronavirus hit worst and all sorts of NPIs had much increased the Germ Gap,
`minimal flu activity is reported, `__ which is consistent with the mechanism for the Germ Gap described.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. _b19-form-sgir-mmv5-fig15-back_2026m04d21:
.. figure:: /_file/pdf/hell/mm/b/19/fig15-germ-gap-overview-simple-sgir.*
:alt: Figure 15 -- Simple overview of the Germ Gap --- the "G" in SGIR models (equivalent to Gap of Germs)
:width: 100%
:align: center
**Fig.15 (full size). Simple overview of the Germ Gap --- the "G" in SGIR models (equivalent to Gap of Germs).**
The core idea of SGIR models is to track how many *Germs*
survive this *Gap* between *Susceptible* and *Infected*
individuals. Reducing this survival is key to controlling a pandemic.
The mechanistic break-down presented here makes the *Germ Gap*
amenable to scientific measurements and mechanistic simulations in
the myriad real-life scenarios that actually control a pandemic.
However, that requires explaining
the SGIR model in *gentle kind reasonable* terms,
because it will be impossible to measure and forecast the myriad relevant forms of the
*Germ Gap* in the real world without strong citizen-science support from
the myriad diverse communities who are the respective experts for
how to parameterize the "as is" status-quo.
Virodefense aims to improve this status quo; but to succeed,
the status quo needs to be thoroughly understood first.
The need to inspire such research motivated Loewe to
work on the work-logic cascades required for organizing corresponding
global Virodefense Olympics.
(:ref:`main text ` | :ref:`list ` |
`download `__)
.. raw:: latex
\newpage
.. References
=============
.. bibliography::
:filter: docname in docnames
.. raw:: latex
\newpage
----
Supplementary Info --- floor pour (MMv5)
==========================================
.. note:: **Floor-pour status (MMv5).** This is the public-floor copy of the SGIR
pandemic study, poured from HELL per the Floor Model (bug c103) and DD b15. The
``mmv5`` marker is the uniform first-Matheo-release tag; it deliberately flattens
real maturity (the HELL source is the more mature ``PPv1``). The exact dated source
and full development context live in HELL (links below). The HUMANE and
author-contribution statements below are a down-payment, to be expanded later.
HUMANE --- working human and AI
--------------------------------------------------
This study was written HUMANEly (HUman MAchine Negotiation Encouraging): a human
and an AI each steelman and stress-test the work, and each catches what the other
misses. For the standard statement of AI use, accountability, and the practical
singularity (PraS) behind this way of working, see Matheo-b21. The cover declarations
(footnotes 6--7) state that AI co-authorship is *withheld* here pending external
peer review of the b21 framework --- the B19 conditional-acknowledgement form.
- *From the human side (LLoL):* [down-payment stub --- to expand.]
- *From the AI side (Claude):* [down-payment stub --- to expand.]
Author contributions (who did what)
--------------------------------------------------
- **LLoL** --- the SGIR modeling and all 2020 figures, structure, key ideas, direction,
and final accountability as sole byline author and senior corresponding author
(title-page footnotes 1--7).
- **AI Claude (Opus 4.6--4.7 Max)** --- drafted and revised the 2026 main text
explaining LLoL's 2020 figures, under LLoL's direction; AI co-authorship is withheld
from the byline pending external review (title-page footnote 6).
- **Everyone** --- invited under the open co-author framework drafted in Matheo-b21
(not on this paper's byline).
(A down-payment; the full who-did-what is to be expanded per the b21 framework.)
Provenance --- where this came from in HELL
--------------------------------------------------
.. caution:: These HELL paths point into the development archive ("datageddon").
They are useful and related, but completeness is not guaranteed and a few may be
imprecise. Treat as a hatch into context, not a clean index. (Intra-floor links and
a proper bibliography wiring are deferred floor tasks --- DD b15 AA #5.)
- **Source this floor copy was poured from:**
``matheology/hell/mm/b/19/b19-sgir_basic-gap-of-germs-2020-epidemiology-ppv1_2026.rst``
- **Development context** (reviews, llogs, prompts) under
``matheology/hell/ll/other/b/19/`` and the 7-panel adversarial review llog
``matheology/hell/ll/study/b/18/study_ll_2026m04d18_sgir-paper-review-llog``.
- **Companion floor papers:** Matheo-b20 (work-logic cascades / Virodefense Olympics /
ResearchCity), the Matheo-b19 Supplementary Information, and Matheo-b21
(the AI co-authorship framework this paper's footnotes 6--7 invoke).
Moved from the original cover (provenance)
--------------------------------------------------
The HELL cover carried draft-scratch source comments (a list of alternate title
candidates, fn-5 hope-line character-counts, and two superseded Broader-Significance
drafts). These are non-rendering RST comments; they were left in place in this floor
copy (and in the untouched HELL original) rather than promoted to visible text.
.. note:: **Naming note (deferred floor tasks).** This copy still carries old
``h*``-era tokens and ``:cite:`` keys resolved against the per-page bibliography;
broken figure ``:ref:`` landings inherited from the HELL draft were neutralised to
plain text during the pour. Notation unification (``h_star`` / ``h_zero`` /
``h_dark``) and citation migration are tracked floor tasks (DD b15 AA #1, #5),
deliberately not rushed here.
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- :doc:`/study/matheo/index` --- the Matheo Study Series overview
- :doc:`/action/audit-the-math/index` --- Audit the Math: the refutation-welcome path
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