Further analysis of the impact of distancing upon the COVID-19 pandemic

This paper questions various claims from the paper "Social distancing strategies for curbing the COVID-19 epidemic" by Kissler, Tedijanto, Lipsitch, and Grad: most importantly, the claim that China's "intense" distancing measures achieved only a 60% reduction in R0.


Introduction
The 22 March 2020 paper "Social distancing strategies for curbing the COVID-19 epidemic" [5] reports calculations in a model where distancing reduces R 0 by at most 60%, and claims that 60% is "on par with the reduction in R 0 achieved in China through intense social distancing measures (3)".
Reference "(3)" is a 9 March 2020 paper [1] that does not say what [5] claims it says. What [1] actually says about the effect of China's distancing upon R 0 is the following: With an early epidemic value of R 0 of 2.5, social distancing would have to reduce transmission by about 60% or less, if the intrinsic transmission potential declines in the warm summer months in the northern hemisphere. This reduction is a big ask, but it did happen in China.
In other words, if R 0 in China was originally 2.5 without distancing, and if China's interventions had less than a 60% effect, then the new R 0 would have been larger than 1, so the epidemic would have continued to spread exponentially in China-but the news reports say that the epidemic was stopped in China, so R 0 there must have been reduced by at least 60%.
How does [5] conclude that "intense" distancing reduces R 0 by at most 60%? There do not seem to be any further comments on this topic in [5]; also, [1] does not seem to present any justification for its claim that reducing R 0 by 60% is a "big ask". Is it plausible that an "intense" lockdown-presumably a drastic reduction in the amount of contact between typical people-would reduce transmission by only 60%? The actual level of reduction directly affects the main quantitative conclusions of [5].
The main objective of this paper is to see what the distancing model in [5] says regarding the initial COVID-19 outbreak and subsequent lockdown in China. The software used in [5] does not seem to be available; this paper is accompanied by new public-domain software intended to implement the same model.
The new computations conclude that, with the minimum R 0 allowed in the model of [5], China would have a 43-day period of hospitalizations being within 50% of peak, and a 53-day period of critical-care cases being within 50% of peak. For comparison, China's reports of "severe cases" between 24 January and 28 March show only a 26-day period of "severe cases" being within 50% of peak.
This comparison is consistent with the theory that "intense" distancing cut China's rate of new infections much more sharply than assumed in [5]. There was no way for [5] to rule out this theory, so [5] should have considered much smaller R 0 values. This paper also covers various other problems with [5].
The theory stated in the previous paragraph should be treated with caution, for several reasons. The hope of strong effects from interventions creates a bias towards believing that such effects exist. Overly optimistic COVID-19 models have slowed down interventions (see, e.g., [2]), and newer models suggest that this slowness will turn out to have caused many unnecessary deaths; further policy decisions based on other unproven theories can be similarly disastrous. There are many other possible explanations for the relatively short period of "severe cases" in China: for example, perhaps increased contact tracing and wearing of masks helped reduce transmission; perhaps changes in treatment or in reporting policies reduced the number of reported "severe" cases.
Furthermore, the fragments of data considered here cannot reliably distinguish between, e.g., the theory that "intense" distancing reduces R 0 by 90% and the theory that "intense" distancing reduces R 0 by 99%. Policymakers trying to find the best combinations of non-pharmaceutical interventions to keep R 0 low until a vaccine is available-for example, keeping it safely below 1, the "dance" explained in [7]-want to know much more regarding the impact of various types of distancing, the impact of encouraging widespread wearing of masks, etc. This paper should not be viewed as answering these questions; this paper merely disputes the overconfident answer given in [2].
The only policy recommendation in this paper is as follows. Governments should systematically allocate 5% of their daily COVID-19 testing capacity to testing people chosen at random from census rolls, with whatever incentives are necessary to create compliance (e.g., in the United States, a $100 reward to each person tested in this way). The resulting data regarding infection rates would help rule out incorrect theories regarding the prevalence of COVID-19, and would provide essential feedback regarding the impact of interventions. No claims of novelty are made regarding this recommendation.

The model
This section reviews [5]'s model of COVID-19 spread.
2.1. Introduction to SIR models. An "SIR model" works as follows. There are N people in the population. This population is partitioned into three subpopulations ("compartments"): • Some people are "susceptible" people who have never been exposed to the disease. The fraction of people who are susceptible is called S, so in total there are SN susceptible people. • Some people are "infectious" people who have been exposed to the disease and could be spreading it. The fraction of people who are infectious is called I, so in total there are IN infectious people. • Some people are "recovered" people who have been exposed to the disease and are no longer spreading it. The fraction of people who are recovered is called R, so in total there are RN recovered people.
The fractions S, I, R have S + I + R = 1. These fractions change over time. Note that the literature often relabels SN, IN, RN as S, I, R, which also changes the equations shown below. Each infectious person is assumed to take, on average, 1/γ days to recover, where γ is a parameter in the model. One can imagine several different ways to define the exact timing of recovery: • Each infectious person recovers after exactly 1/γ days. (There is no variance in the recovery time.) • Each infectious person has probability γ of recovering each day. (There is much more variance in the recovery time.) • Each infectious person has probability γ/24 of recovering each hour.
• Et cetera. An SIR model uses the limit of these possibilities, continuously compounding the probability of recovery. Mathematically, if there are no new infections, then this model says that the derivative I (t) is −γI(t) where t is time measured in days, so I(t) = I(0) exp(−γt).
Meanwhile each infectious person is assumed to transmit the disease to an average of β people each day, spread uniformly at random through the entire population. This transmission affects only susceptible people: each infectious person infects, on average, βS people each day. The IN infectious people are assumed to infect separate people, a total of βISN people on average each day, increasing I at a rate βIS. This again is modeled as a continuous process: diagrams for discrete automata should observe that the notation here does not include self-loops, the default possibility of staying in the current compartment.
Without doing the work of analyzing solutions to these equations, one can guess that each infectious person will transmit the disease to an average of β/γ people, and thus infect an average of (β/γ)S people, during the 1/γ days of an average infection. The ratio β/γ is called R 0 . This back-of-the-envelope calculation suggests that an epidemic with R 0 < 1 will remain under control, while an epidemic with R 0 > 1 will explode exponentially until S drops to 1/R 0 ("herd immunity").
One can see the same effects in the model: any nonzero rate of infectious people will increase (i.e., I (t) > 0) as long as βS(t) > γ, i.e., R 0 S(t) > 1. Once S(t) drops to 1/R 0 , the quantity I(t) stops increasing. The remaining infectious people continue infecting more, pushing S(t) somewhat below 1/R 0 , but the recovery rate begins to reduce I(t).

General issues with SIR models.
Real diseases seem to be less infectious at first but become more infectious after an incubation period; an SIR model does not account for this. An "SEIR model" tries to address this by adding an extra compartment for "exposed" people who are infected but not yet infectious: These equations are abbreviated "S βI −→ E ν − → I γ − → R". The equations say that an exposed person takes, on average, 1/ν days to become infectious. Note that this delay slows down the progress of the epidemic, but also slows down the effect of interventions that are based only on observations of I and not on observations of E.
Real diseases also have different effects on different people-and, presumably, different levels of transmission-but SIR models and SEIR models do not account for this. The paper [5] tries to address this for COVID-19 by modeling three different levels of disease severity: • Mild infections ("I R ") progress to recovery ("R R ").
• Moderate infections ("I H ") progress to hospitalization ("H H "), and then progress to recovery ("R H "). • Critical infections ("I C ") progress to hospitalization ("H C "), and then to critical care ("C C "), and then to recovery ("R C ").
The model thus has 11 compartments (including S and E). This makes the model sound more complicated than it actually is: one can compute the same results with just 7 compartments, namely S, E, I = I R + I H + I C , H H , H C , More broadly, when someone objects that an SIR/SEIR model is oversimplified, the standard response is to add more transitions to the model. For example: any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint • Perhaps observations show that immunity lapses. The standard response is to add an R → S transition. • Perhaps the observed variance of progression times for a disease is smaller than predicted in an SEIR model. The standard response is to add more stages of progression, such as S → E 1 → E 2 → I 1 → I 2 → R, narrowing the variance while preserving the average. • Perhaps the period of infectiousness begins before the period of symptoms, and people with symptoms take more precautions to reduce transmission. The standard response-assuming, e.g., an S → E 1 → E 2 → I 1 → I 2 → R model-is to model a larger transmission speed from I 1 than from I 2 . The terminology used for such a model distinguishes the "latent period", meaning the non-infectious time spent in E, from the "incubation period", meaning the pre-symptomatic time spent in E and I 1 . • Part of the rationale for health-care workers to wear protective equipment is that hospitalized and critical-care patients-and the health-care workers themselves-are believed to be sources of infection. This is not accounted for in the model of [5]. The standard response would be to add further compartments to track infections of health-care workers. • People are spread around the globe. Infections are sometimes carried by travelers or possibly by packages, but presumably infections are much more likely to spread locally. The standard response is to have local compartments, perhaps with different transmission rates that try to account for local factors such as population density and frequency of mask use. All of these models depend heavily upon parameters such as β and γ. Small mistakes in estimating those parameters can easily produce vastly larger errors in predictions. This difficulty is exacerbated by the practice of adding more and more compartments to models, along with more and more dimensions in the parameter space, since the problem of computing parameters accurately from output data typically becomes exponentially more difficult as the dimension grows. Furthermore, modeling a discrete probabilistic process as a continuous deterministic process becomes increasingly difficult to justify as the number of compartments increases. [5]. In the model of [5], the speed (per day) of progression from being infectious (I → R or I → H H or I → H C , depending on the disease severity) is 1/5 ("γ"); the speed of progression from hospitalization to recovery (H H → R) for moderate cases is 1/8 ("δ H "); the speed of progression from hospitalization to critical care (H C → C) is 1/6 ("δ C "); and the speed of progression from critical care to recovery (C → R) is 1/10 ("ξ C "). The speed of progression from being exposed to being infectious is not stated in [5] but appears to be modeled as 1/5.

Parameters in
In this model, a critical infection takes an average of 5+5+6 = 16 days before critical care, and an average of 16 + 10 = 26 days before the end of critical care. After a rapid burst of new infections, an intervention that drastically reduces new infections would not produce a peak of critical-care patients in this model until about three weeks later. any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint The model of [5] assumes that 95.6% of infections are mild while the other 4.4% require hospitalization. The procedures that have produced these numbers are not robust, as emphasized in [3], but this paper's policy recommendation (see Section 1) would rapidly produce robust numbers. This is not an endorsement of the controversial idea from [3] of delaying serious interventions until robust numbers are available.
There is one more parameter in the model of [5], the most important parameter: namely, R 0 , which in turn determines β = γR 0 . This is modeled in five stages: • The wintertime R 0 is modeled as either 2 or 2.5. Beware that the literature includes a wider range of estimates for R 0 , and underestimating R 0 is dangerous. • The summertime R 0 is modeled as either 70% (more optimistic) or 100% (less optimistic) of the wintertime R 0 . • The current-time R 0 is modeled as a cosine curve from the wintertime R 0 down to the summertime R 0 and back up. The maximum is assumed to occur 3.8 weeks (26.6 days) before the end of the year. • The distancing R 0 takes 0%, 20%, 40%, or 60% away from the currenttime R 0 , reflecting four different hypotheses regarding the effectiveness of distancing. • The final R 0 is modeled as either the current-time R 0 or the distancing R 0 , depending on whether distancing is "on" or "off".
The paper analyzes the consequences in this model of a few different strategies for deciding when to turn distancing on or off. To summarize, the differential equations for the model of [5] are as follows, where R 0 is the final R 0 defined above: As mentioned earlier, this is presented with 11 compartments in [5], but these 7 compartments produce the same results in a simpler way.

2.4.
Further issues with the model. According to Wikipedia, more than 10000 people in Italy have been reported dead with COVID-19 at the time of this writing, including more than 600 per day for each of the past 9 days. It is plausible (although not proven) that almost all of those deaths were not merely any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint with COVID-19 but caused by COVID-19; and that if COVID-19 is not brought under control then it will cause millions of deaths worldwide within a year.
Perhaps many of these deaths can be avoided through, e.g., widespread mask usage, combined with several periods of distancing over the next year, followed by widespread vaccination. However, this cannot even be expressed, let alone analyzed, in the model of [5]: • The model includes on/off distancing, but does not include masks or any other non-pharmaceutical interventions. • The model does not include the possibility of future vaccination (S → R).
• The model does not include deaths. Dead people are treated as "recovered"they have been exposed to the disease and are no longer spreading it. This simplification does not change the analysis of the spread of the epidemic, but the terminology is ethically questionable and presumably reduces the amount of attention given to one of the most important variables.
All of the parameters and distancing strategies considered in [5] result in mass COVID-19 infection within a few years-but a closer look shows that some scenarios have far fewer infections than others by mid-2021. In an extended model that accounts for deaths and the possibility of widespread vaccination, these scenarios would have far fewer deaths than other scenarios. There could be an even larger reduction in COVID-19 infections and deaths if non-pharmaceutical interventions are more effective than assumed in [5]. This again highlights the importance of understanding the actual impact of distancing, masks, etc.

What the model predicts for hypothetical future United States distancing
This section reviews, and disputes some of, (1) the calculations that [5] carries out within its model, and (2) the conclusions that [5] claims on the basis of these calculations.
3.1. Software engineering. https://cr.yp.to/2020/gigo-20200329.py, an attachment to this paper, is a Python script that produces (as PDF files) all of the graphs shown here. As noted in Section 1, the software used in [5] does not seem to be available. It is easy to find software online for other SIR/SEIR/. . . models, including software that appears reasonably easy to adapt to the model of [5], but all of this software seems to depend on ODE-solving packages (e.g., scipy.integrate.odeint), and it is not clear how much review those packages have had from a safetyengineering perspective. This paper's Python script begins with a table of transitions, for example expressing E 1/5 − − → I as follows: ('E','I',1/5.0) Transition speeds can be functions: for example, the transition any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint ('S','E',paperinitialpulse) uses the following function: def paperinitialpulse(day,distancing): return 0.01/7 if day < startday+3.5 else 0 This appears to match the description in [5] of how the initial infection is modeled: "infection is introduced through a half-week pulse in the force of infection". The height of this pulse is not stated in [5], but an earlier paper suggests 0.01 per week. The most complicated transition is This matches the main distancing strategy highlighted in [5], where distancing is "turned 'on' when the prevalence of infection rose above . . . 37.5 cases per 10,000 people", and off when the prevalence drops below 10.0 cases per 10,000 any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint people. ("Infection" here appears to refer specifically to the I compartment, so it should have said "infectiousness".) If these calculations were performed in exact arithmetic (or interval arithmetic in higher and higher precision), rather than floating-point arithmetic, then the outputs over any compact interval would converge to the exact solution of the equations as daydelta converges down to 0. This does not imply that the outputs of the Python script are exact: the script uses floating-point arithmetic and a specific nonzero daydelta. More precisely, the script takes daydelta as 1/72 days (20 minutes), but decreases daydelta towards 0 when I approaches the 37.5/10000 or 10.0/10000 cutoffs. Some spot-checks suggest that smaller choices of daydelta produce visually identical graphs, but this is very far from a thorough error analysis.
Differential equations are normally solved by more complicated algorithms that are designed to obtain better tradeoffs between equation-solving time and accuracy. However, simpler algorithms are easier to review. The first 98 lines of this Python script include the transition tables, underlying functions, differentialequation solver, and recording the history of output data, using no libraries other than π and cos. The script then has more lines-which also need review!-for turning the data into graphs using matplotlib, a relatively complicated library. [5]. The paper [5] claims, within its model, that the (37.5, 10.0) distancing strategy explained above achieves the "goal of keeping the number of critical care patients below 0.89 per 10,000 adults" under the following assumptions: wintertime R 0 = 2, and distancing achieves a 60% reduction in R 0 . This conclusion is stated for both the "seasonal and non-seasonal cases", i.e., for summertime R 0 being either 70% or 100% of the wintertime R 0 .

Disputing the calculations in
The conclusion is backed by a non-seasonal graph [5, Figure 3(A)] and by a seasonal graph [5, Figure 3(B)]. The seasonal graph comes close to exceeding 0.89 (in July 2021), but does not exceed it. The (37.5, 10.0) choice is close to, but not at, the edge of safe possibilities shown in [5, Figure S3]. The assumption that R 0 = 2 is important: other graphs [5, Figures S6(A), S6(B)] say that this distancing strategy does not achieve the goal if R 0 = 2.5. The orange curve shows 10000H = 10000H H + 10000H C (which is not plotted in [5]). As expected, each peak of infectiousness (black) triggers a later peak of hospitalizations (orange), followed by a peak of critical-care patients (red). These graphs go several months beyond the graphs in [5], so it is unsurprising that they show an extra period of distancing.
The second and third plots are two different recalculations of the seasonal [5, Figure 3(B)]. The second plot seems to match [5, Figure 3(B)]. The third plot looks the same at the beginning, but looks different in 2022, and in particular any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14. crosses the 0.89 line. The only difference between the models used in the second and third plots is as follows: • One of the plots uses a 52-week seasonality period as specified in [5].
• The other plot is a calculation in a model that was modified through the introduction of a typographical error, replacing 52 with 55.
This illustrates how safety conclusions can be undermined by errors hidden inside epidemic-modeling software. This illustration is not hypothetical: the second plot, the one that seems to match [5, Figure 3(B)], is the one that includes the typographical error.
If the third plot here is correct then the (37.5, 10.0) safety claim in [5] is wrong. Occam's razor suggests that the safety claim in [5], and the underlying calculations in [5], arise from the typographical error mentioned above. any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint In all of these models, the distancing trigger creates an immediate reduction in E, a less sharp reduction in I within a week, and a reduction in C in under a month. For comparison, peaks in I that occur without intervention (because 1 − S has increased enough compared to R 0 ) continue to trigger new infections for some time, and relatively large peaks in C. This is why the mid-2022 redversus-black gap in the third plot is relatively large compared to the other redversus-black gaps: a peak in I occurs just below the trigger for intervention. It should be clear that this variation can occur within this model, even under the assumptions that (1) there are mistakes in the third plot and (2) a corrected version of the same plot would not show this variation.
One can see this variation in gaps in [5, Figure S6(D)], but these phenomenaand their safety consequences-do not seem to have been noted in [5]. The error analyses in [5] were too limited to catch this error, and there is no evidence that the software was subjected to any double-checks or other review.
One can respond that 0.89 is not exceeded by much in the third plot, and that we should have enough critical-care capacity by then to handle this. Such a response is missing the broader point. If a change from 52 to 55 was not caught, why should one expect larger errors to be caught? Current practices in modeling epidemics obviously do not have adequate guarantees of the correctness of software claimed to be implementing models. The dangers of inaccuracies in computations are added to the dangers of inaccuracies in the models per se.
Email dated 25 Mar 2020 05:19:27 -0000 to the contact authors for [5] included a preliminary public version of this paper's Python script, noted the discrepancy with [5, Figure 3(B)], noted the contradiction with the (37.5, 10.0) safety claim, and suggested posting software "for public review so that errors can be more easily located and corrected". This email did not elicit a response. Considerable effort spent reverse-engineering [5, Figure 3(B)] eventually identified the theory of a 55 typographical error. The unavailability of the software continues to make the theory unnecessarily difficult to confirm.
As further checks on this paper's Python script, Figure 3.4 includes the same calculations for R 0 = 2.5. Compare the top two plots to [5, Figures S6(A), S6(B)].
3.5. Implementability of distancing strategies. Recall that this distancing strategy is triggered by I crossing particular cutoffs, namely 37.5/10000 and 10.0/10000. A policymaker considering this strategy immediately runs into the problem that the real-world I is unknown at each moment. (This is separate from the question of whether the strategy is safe; see above.) The paper [5] claims that, to "implement an effective intermittent social distancing strategy", it will be "necessary to carry out widespread surveillance to monitor when the prevalence thresholds that trigger the beginning or end of distancing have been crossed".
Collecting data regarding COVID-19 prevalence is valuable for other reasons, and is the only policy recommendation in this paper. This does not imply, however, that such data collection would enable implementation of the strategy in [5] with a useful level of accuracy. An error analysis is required here-accounting any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14. for lags in testing, errors in testing, possible correlations between infectiousness and non-compliance, etc.-but does not appear in [5]. Furthermore, no justification is provided in [5] for the claim that this data collection is "necessary" for a distancing strategy to be "effective". Imagine policymakers today implementing a simple one-month-on-one-month-off distancing strategy to be adjusted later; this is effective in some of the scenarios covered by the paper's model, contradicting the blanket claim of ineffectivity. Perhaps this simple strategy is unimplementable for cost reasons or political reasons, but this does not justify the claim that the strategy is ineffective.
3.6. The effect of increased critical-care capacity. The obvious way to handle the possibility of overruns in critical-care capacity is to increase the criticalcare capacity. This is not controversial. any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . What is much more controversial is the idea of actively trying to exploit all available critical-care capacity, tuning the amount of distancing to almost-but not quite-overload this capacity. One reason this is controversial is that such tuning is prone to error, whether the errors come from miscalculations within models (as illustrated above) or from the models being wrong; see, e.g., [8]. Another, more fundamental, reason this is controversial is that less distancing means more infections. The claim that these infections are inevitable might be correct but (1) is not justifiable from the available data and (2) does not justify policy decisions that make the infections happen now.
The paper [5] claims that increasing critical-care capacity "allows population immunity to be accumulated more rapidly, reducing the overall duration of the epidemic and the total length of social distancing measures". It is not ethical to say that exploiting increased critical-care capacity in this way is "allowed" without mentioning that this has the side effect of more infections now-including painful hospitalizations and deaths that would have been avoided by more distancing. Furthermore, the predictions made by the model of [5], in particular regarding the epidemic duration and the amount of distancing, are not robust against modifications to the model that account for more effective interventions and the possibility of widespread mid-2021 vaccinations.
The paper [5] also claims, in its "Summary" at the top, that "Intermittent efforts require greater hospital capacity". This is contradicted by, e.g., [5, Figure  3(B)], which claims-for R 0 = 2 with seasonality-that the capacity of 0.89 critical-care beds per 10000 adults would not be overrun with (roughly) halftime intermittent distancing in 2020 and less distancing in subsequent years.
The second claim appears to be based on a miscalculation, as noted above, but correcting this miscalculation and adding more distancing in subsequent years would again contradict the "require" claim.
This criticism of various unjustified claims in [5] should not be interpreted as opposition to the idea of increasing hospital capacity. Current news reports and simple extrapolations are consistent with the theory that the United States will already need more than 0.89 critical-care beds per 10000 adults in April, as a direct result of inadequate initial interventions in March.
3.7. The possibility of interventions being more effective than assumed in the model. The first sentence of the summary of [5] is as follows: "One-time distancing results in a fall COVID-19 peak." As for intermittent distancing, the paper's lead author [4] summarizes the paper's main quantitative conclusion as follows: Intermittent social distancing can prevent critical care capacity from being exceeded but such measures may be required for 12-18 months. Depending on R0 and the amount of seasonality, social distancing must be 'on' for as little as 25% but up to 70% of the time.
The paper itself says that staying below 0.89 requires "social distancing measures to be in place between 25% . . . and 70% of that time" (into 2022). These claims could be correct, but they go beyond what is shown in the paper. any purpose without crediting the original authors.
Concretely, the paper shows within its model that a single month of distancing now will not prevent mass infection by October; and that extending this to, say, three months will not prevent mass infection by the end of the year. The paper also shows within its model that a particular intermittent-distancing strategy, applied between 25% and 70% of the time, comes close to 0.89/10000 criticalcare patients again and again. It is reasonable to conjecture that, within this model, every intermittent-distancing strategy with fewer than 6 months of total distancing will break the 1/10000 barrier.
However, all of these conclusions depend upon the exact values of R 0 during and after distancing. Perhaps the effect of distancing is stronger than assumed any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint in [5]. Perhaps other interventions-increased hand-washing, increased wearing of masks and mask substitutes, etc.; see [7] for many more possibilities-will keep R 0 below 1 after one-time distancing. As examples of how heavily the results depend upon hypotheses regarding the effectiveness of interventions, Figure 3.8 shows what happens with the following strategies and extensions of the model: (1) distancing reduces R 0 by 80%; (2) distancing is turned off at 2.0/10000, and reduces R 0 by 99%; (3) same but with R 0 starting at 1.5 instead of 2, as a model of non-distancing interventions reducing transmission by 25%. The clear differences between the graphs again highlight how important it is to understand the actual impact of interventions.

What the model predicts for actual China distancing
This section returns to the claim in [5] that a 60% reduction in R 0 is "on par with the reduction in R 0 achieved in China through intense social distancing measures". As noted in Section 1, this claim is incorrectly attributed to [1], and is not otherwise justified in [5]. Sections 2 and 3 have highlighted the importance of understanding what R 0 can actually be achieved. Figure 4.2 contains four more plots produced by the same Python script used in Section 3. Each plot stretches over a 4-month period, includes 52-week seasonal forcing, and includes "intense" distancing starting on 23 January 2020.

Computations in the model.
The second plot takes the wintertime R 0 to be 2.0, the most optimistic possibility allowed in [5]. "Intense" distancing is assumed to reduce R 0 by 60%, again the most optimistic possibility allowed in [5].
The first (less optimistic) plot takes the wintertime R 0 to be 2.5. The third (more optimistic) plot takes the wintertime R 0 to be 2.0 and uses an extended model where "intense" distancing has more of an effect, reducing R 0 by 99%. The fourth plot is like the third but takes the wintertime R 0 to be 3.5.
In each plot, there is an initial 2-day pulse of exposure. This is chosen shorter than the half-week pulse from [5] to limit the impact of the pulse time upon the width of the resulting peaks. The pulse starts on 11 January, 5 January, 1 January, and 10 January respectively; these dates are chosen so that the red curves have approximately the same peak heights, simplifying comparison of other features of the curves.

4.3.
Reported "severe cases" from China. https://cr.yp.to/2020/nhc-20200329.py is a Python script that is intended to plot, for each day, the number of cases reported by China's NHC as being "severe" on that day. The data incorporated into the script was extracted manually, with considerable help from Google Translate, from http://www.nhc.gov.cn/yjb/pzhgli/new_list. shtml, the primary source of China COVID-19 case counts cited by Wikipedia. Double-checking the data, and other aspects of the script, would be useful. The output of the script is shown in Figure 4 The reason for selecting reports of "severe" cases, rather than (e.g.) reports of "confirmed" cases, is the common-sense guess that more severe cases are more any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14. What the model from [5] predicts regarding a lockdown in China starting 23 January 2020. First plot: R 0 = 2.5, with 60% reduction from distancing, with initial 2-day pulse starting 11 January 2020. Second plot: R 0 = 2, with 60% reduction from distancing, with initial 2-day pulse starting 5 January 2020. Third plot: R 0 = 2, in an extended model with 99% reduction from distancing, with initial 2-day pulse starting 1 January 2020. Fourth plot: R 0 = 3.5, in an extended model with 99% reduction from distancing, with initial 2-day pulse starting 10 January 2020. See text for more details.
any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14. likely to be tested and reported, hopefully producing a curve close to reality. However, there could still be biases in the testing or reporting procedures, and the NHC reports do not state the exact definition of a "severe" case. This raises the question of how to build a model that is not obviously inconsistent with the NHC reports-while at the same time avoiding the clear danger of overfitting. There are several contributing factors to the widths of the peaks in Figure 4.2. In the first plot, wintertime R 0 = 2.5 is reduced by distancing to 1, so the epidemic is controlled primarily by seasonal forcing (plus a gradual increase in 1 − S, the green curve). This is not a large effect, so new infections continue to occur for a long time. This phenomenon is smaller in the second plot, with wintertime R 0 = 2, and much smaller in the third and fourth plots.
The width of the E peak (not plotted) then produces a somewhat wider I peak (the black curve), since E → I has a high variance. This in turn produces a somewhat wider H peak (the orange curve) followed by a somewhat wider C peak (the red curve).
As noted in Section 2, SEIR models are easily adjusted to match observations of lower variance in an individual's disease progression. For example, the analysis of [6] indicates that the COVID-19 incubation time has standard deviation only about half of its mean. Modifying the model of [5] to include more E stages any purpose without crediting the original authors.
for peer-reviewed) in the Public Domain. It is no longer restricted by copyright. Anyone can legally share, reuse, remix, or adapt this material The copyright holder has placed this preprint (which was not . https://doi.org/10.1101/2020.04.14.20048025 doi: medRxiv preprint (while preserving the mean) would reduce the width of the resulting I, H, and C peaks, producing a sharper increase towards the maximum and the a sharper decrease from the maximum. It is also easy to adjust the model of [5] to delay the C peak.
However, a large part of the width of the peak in the first and second plots in Figure 4.2 arises directly from the assumption that R 0 is large even after distancing. It is not obvious how to reconcile the model of [5] with the reports from Figure 4.4 without dropping this assumption.
This analysis should not be interpreted as confidently concluding that [5] is wrong in claiming that China achieved only a 60% reduction in R 0 . One can imagine various ways that the claim could still be correct. However, [5] is not justified in the level of confidence that it states in this claim, and is not justified in the level of confidence that it states in the conclusions that rely on this claim.