Identification of the Turning Point

To avoid the prediction difficulties caused by fluctuation of the basic reproduction number R0, we use the logistic and Gompertz function to predict confirmed COVID-19 cases in the United States. To increase the robustness of prediction, we will apply 4 models based on logistic and Gompertz functions (see Table 2). A logistic function is a typical “S” shape (sigmoid curve), while the Gompertz function is an asymmetric sigmoid shape (see Figure 1). In other words, the logistic model has the property of being symmetrical about the inflection point, while Gompertz curve is asymmetrical about the inflection point.^{Reference Dhar and Bhattacharya17}

TABLE 2 Logistic and Gompertz Functions

FIGURE 1 Logistic and Gompertz curve.

In logistic and Gompertz functions, y represents the evolution of the epidemic in the United States, which is the cumulative confirmed cases of COVID-19. t stands for time. Both log4 and log3 are logistic functions: log4 is a logistic function with intercept term b0, and log3 is the logistic function without an intercept term. Both gom4 and gom3 are Gompertz functions: gom4 is the Gompertz function with intercept term b0, and gom3 is the Gompertz function without an intercept term. b1 is the curve’s maximum value. b2 is the steepness of the curve. b3 is the t-value of the sigmoid’s midpoint.

The trajectories predicted by 4 models represent 4 paths that may appear in COVID-19’s transmission. As external conditions change, the cumulative number of confirmed cases may follow either trajectory. Examining the peaks of the 4 paths will help identify the turning point of COVID-19 in the United States.

Based on the 4 models in Table 1, path _log4 , path _log3 , path _gom4 , and path _gom3 are the 4 predicted trajectories. Suppose 4 paths reached their peak at time T1, T2, T3, and T4, respectively, which needs to meet the following conditions.

(1) $${\it\Delta} path_{\log 4}^{T1} < 0\hbox.1\hbox,\,{\it\Delta} path_{\log 3}^{T2} < 0\hbox.1\hbox,\,{\mkern 1mu} {\it\Delta} path_{gom4}^{T3} < 0\hbox.1\hbox,\,{\mkern 1mu} {\it\Delta} path_{gom3}^{T4} < 0\hbox.1$$

The meaning of constraint Equation (1) is that the daily increase of confirmed cases at the peak must be less than 0.1. In other words, the cumulative confirmed cases of COVID-19 at the peak of 4 predicted trajectories would remain stable. However, it is difficult to claim that the pandemic will reach a maximum if there is significant divergence among T1, T2, T3, and T4. To confirm the turning point for a specific state in the United States, the 4 predicted trajectories need to converge. After identifying T1, T2, T3, and T4 based on Equation (1), the time interval between the turning point of the highest path and the lowest path is defined as follows.

(2) $$Perio{d_i} = \left| {Max(T1\hbox,T2\hbox,T3\hbox,T4) - Min(T1\hbox,T2\hbox,T3\hbox,T4)} \right|$$

Therefore, the following constraint must hold for an identified turning point.

(3) $$Perio{d_i} \le 14$$

When the constraint Equation (3) holds, the time interval between the most pessimistic and optimistic turning points is less than or equal to 2 wk. Then it can be inferred that the 4 predicted trajectories would converge under constraint Equation (3). As a result, we can claim with confidence that the identified turning point lies between Min(T1, T2, T3, T4) and Max(T1, T2, T3, T4). If the constraint Equation (3) does not hold, we can conclude that it is still too early to determine the turning point based on the historical data of cumulative confirmed cases of COVID-19. However, it should be mentioned that the models used here rely on a closed nonmobile population. Since the death of George Floyd, the Black Lives Matter movement, which began on May 26, has led to large scale protests in the United States. Therefore, the model might apply to the period before May 26.

Severity Ratings of COVID-19

To rate the severity of COVID-19 spreading in the states, we take into account 2 crucial factors, namely the uncertainty of the outbreak and the gravity of the current circumstances. We collected data of COVID-19 outbreak in the United States from Wind Data Service, which is a market leader in China’s financial information services industry. We selected the sample period from January 21 to May 25, 2020, to make prediction, since Black Lives Matter protests across the United States happened after May 25. As noted before, the model used in this study depends on a closed nonmobile population. Thus, we apply the model to make estimation using the sample before May 26. To have a better view of the severity of COVID-19, turning points for 50 states and Washington D.C. are predicted.

(1) Construction of Uncertainty Index

As is shown in Equation (2), Period_i is the time interval between the turning point of the highest path and the lowest path, which represents the uncertainty of the epidemic trend. There will be less uncertainty about the epidemic trend if the value Period_i is smaller. We further standardized them to eliminate the influence of the dimension as below.

(4) $$Period_i^{std} = {\frac{{Perio{d_i} - \mathop {\min }\limits_{1 \le j \le n} \left\{ {Perio{d_j}} \right\}}}\over{{\mathop {\max }\limits_{1 \le j \le n} \left\{ {Perio{d_j}} \right\} - \mathop {\min }\limits_{1 \le j \le n} \left\{ {Perio{d_j}} \right\}}}$$

(2) The Severity of the Epidemic

We use the number of existing confirmed cases to measure the severity of the current situation, which is defined as follows.

(5) $$Patien{t_i} = Confirme{d_i} - deat{h_i} - cure{d_i}$$

As is shown in Equation (5), the total number of existing confirmed cases in state i (Patient_i) equals the cumulative number of confirmed cases (Confirmed_i) minus the cumulative number of deaths (death_i) and the cumulative number of recovered cases (cured_i).The data provider of the 3 indicators is Wind Data Service. To minimize the effect of dimension, we calculated the proportion of existing confirmed cases as below.

(6) $$rati{o_i} = {\frac{{Patien{t_i}}}\over{{\sum\limits_{j = 1}^n {Patien{t_j}} }}$$

As is shown in Equation (6), ratio_i can be used to measure the severity of the epidemic in state i. As ratio_i becomes larger, coronavirus spread in state i is more severe.

(3) Index of Severity Ratings for COVID-19

Combining information on uncertainty and severity, we construct the index of severity ratings as below.

(7) $$Leve{l_i} = Period_i^{std} \cdot rati{o_i} \cdot 100$$

As mentioned above, a larger value of $Period_i^{std}$ means greater uncertainty, while a larger ratio_i means more severe of the epidemic in terms of existing confirmed cases. Therefore, as the index of severity rating Level_i increases, the severity ratings for state i will rise accordingly. The severity index in Equation (7) takes into account both uncertainty and severity information, which can provide a reasonable evaluation of severity ratings for COVID-19 in the United States.

According to the estimation value of Level_i, it is possible to divide different regions of the United States into 4 categories based on severity degree (Table 3). Using the information on first, second, and third quartile, we can identify regions with high risk, medium-high risk, medium-low risk, and low risk. To be more specific, if Level_i lies between first and third quartile, then region i can be identified as medium risk areas. The second quartile is used to separate medium-high risk from medium-low risk areas. If Level_i lies below first quartile or above third quartile, then region i can be identified as low risk area or high risk area.

TABLE 3 Severity Rating of COVID-19

Note: Q1, Q2, Q3 are the first, second, and third quartile respectively. Inter-quartile range is the distance between the first and third quartiles.

Furthermore, by identifying outliers with the 1.5 × IQR rule, it is possible to distinguish extremely high-risk and extremely low-risk areas within high risk and low risk areas, respectively. To be more specific, if Level_i is greater than Q3 + 1\hbox.5*IQR, then region i can be classified as extremely high-risk region within high risk group. If Level_i is less than Q1 – 1.5*IQR, then region i can be classified as extremely low-risk areas within low risk group. There are 4 possibilities. First, there are no outliers for the index of severity rating. In this case, there is no extremely high-risk or extremely low-risk areas. Second, there might be only high outliers. In this case, we can distinguish extremely high-risk areas within high risk group. Third, there might be only low outliers. In this case, we can distinguish extremely low-risk areas within low risk group. Fourth, there might be both high and low outliers. In this case, we can distinguish both extremely high-risk and extremely low-risk areas within high risk group and low risk group, respectively.