Data acquisition

The data for the present article were downloaded from the ICEWS repository on Harvard University’s Dataverse using the ICEWS R package (Beger, Reference Beger2021). The ICEWS “is an early warning system designed to help US policy analysts predict a variety of international crises to which the US might have to respond (…).” This project was created by the Defense Advanced Research Projects Agency but has since been funded (through 2013) by the Office of Naval Research (Ward et al., Reference Ward, Beger, Cutler, Dickenson, Dorff and Radford2013, p. 1). The ICEWS is based on fully automated machine coding of news items from “over 6,000 international, regional, national and local news sources” (Boiney and Foster, Reference Boiney and Foster2013, p. 48). It is an example of what is known as automated event coders: “[A]utomated event coders code natural language text (usually from news sources) as categories of events” (Kotzé et al., Reference Kotzé, Senekal and Daelemans2020, p. 1). The coding was conducted “to extract <who, did-what, to-whom, when, where>, and performs updates in near-real time” (Boiney and Foster, Reference Boiney and Foster2013, p. 48).

The full ICEWS dataset retrieved on August 18th, 2021 consists of 19,140,780 observations for the time period January 1995 through August 2021. It was subset as described below into the main dataset used in the current study for the same timeframe. That dataset included 120,299 observations. A smaller dataset was extracted for the timeframe April 2010 to March 2012 as described below. It included 71,036 observations. The following sections describe the analysis conducted. The first part is a replication of Yonamine’s (Reference Yonamine2013) study for the period of April 2010–March 2012. The data for this timeframe were divided similarly to the original study to an ITS (September 2004–March 2010) and a TS (April 2010–March 2012).Footnote ⁹ The second part compared the results to those of Yonamine (Reference Yonamine2013). The comparison was used to assess the validity of the original study’s conclusions, which were based on GDELT data, to the employment of this approach on ICEWS data.

Drawing on the conclusions of this comparison, the third part employed Yonamine’s (Reference Yonamine2013) approach to predicting violent events in Afghanistan over a significantly longer period of time (January 1995–August 2021). The division into ITS and TS was based on backtesting. The conclusions of this section provide an assessment, based on the methods and data source used, of the prevalent argument in literature whereby, for the time being, the best predictions for which we can hope are near future, georeferenced ones.

Data preprocessing

The present article focuses on events in Afghanistan, and therefore, the first step was to subset all events that took place in Afghanistan using the ICEWS “country” variable, which was set to “Afghanistan.” Moreover, concentrating on physical violent events required a way of identifying and extracting them. ICEWS enables this as it classifies data according to the Conflict and Mediation Event Observations (CAMEO) typology (Ward et al., Reference Ward, Beger, Cutler, Dickenson, Dorff and Radford2013, p. 1).Footnote ¹⁰ The CAMEO ontology captures the action which took place, as well as its direction, between two actors. Each observation is identified by a unique code of either three or four digits. The identifiers were used to assign a quad code to each observation. These quad codes were used to create “quad counts” of the events in the following categories (Chiba and Gleditsch, Reference Chiba and Gleditsch2017, p. 278). Each category’s quad code classification appears alongside it in brackets: verbal-cooperation (a); material-cooperation (b); verbal-conflict (c); and material-conflict (d).

Despite their demonstrated utility, some argued that quad counts “are useful for distilling complex data sets into simple variables but are too coarse to capture the dynamics of escalation and de-escalation that procedural theories propose” (Blair and Sambanis, Reference Blair and Sambanis2020, p. 1890). This critique does not pertain to the current study, however, as it does not focus on capturing conflict dynamics but on event prediction only. However, this may hinder the use of quad counts for engagements with the literature on state-building failure and violence in Afghanistan, which are focused on identifying and explaining the mechanisms driving violence.

Because the article centers on the prediction of political conflict events in their spatial settings, events had to be matched to the places in which they occurred. To do so, use was made of the observations’ longitude and latitude variables,Footnote ¹¹ which are provided as part of the ICEWS data. The coordinates were used to geolocate the event within its administrative unit, that is, district or province, requiring reliable, detailed data on the division of Afghanistan into its respective administrative units. This information was retrieved from the Global Administrative Areas (GADM) dataset (Global Administrative Areas, 2012). Its country data files on Afghanistan were used to assign the coordinates of events to the required administrative units via a customized function.Footnote ¹² The latter conducts reversed geocoding that assigns an administrative unit’s name (e.g., district or province) to a new variable (i.e., either “district2” or “province2”). Overall, 318 districts and 34 provincesFootnote ¹³ were identified by their unique names.Footnote ¹⁴ Subsequently, as a final step, the observations which were classified as “quad 4,” that is, material-conflict, were subset.

The resulting dataset contains 120,299 observations of material conflict for the period beginning in January 1995 and ending in August 2021.Footnote ¹⁵ In order to provide some insight into the dataset, Figure 1 presents the total number of cases per year, that is, at the country level. The variable Kabul_pro presents the proportion of total events in Afghanistan that occurred in the district of Kabul City.

Figure 1. Number of violent events per year, 1995–August 2021. Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

As shown in Figure 1, the height of each bar signifies the total number of quad four events for Afghanistan each year. The color of the bars shows the proportion of these events that took place in the district of Kabul City, where lighter colors correspond to greater proportion. Overall, there are relatively few events up to 2001, which saw a significant increase following the American invasion and subsequent occupation of Afghanistan. Moreover, the events from 1995, 1996, and 2001 were particularly concentrated in Kabul.

In order to verify that the American invasion of Afghanistan had indeed constituted a turning point in the number of violent events, Figure 2 presents the number of violent events per month for 2001.

Figure 2. Events per month in Afghanistan in 2001. Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Figure 2 indicates that the invasion in October 2001 was indeed a turning point with a major increase in the number of violent events from September onwards. Figure 1 further indicates that the number of events in the following years is influenced by the turbulent years of American involvement in Afghanistan. Moreover, the smaller number of events prior to 2000 was probably also influenced by the relative lack of media attention to the developments in Afghanistan before the 9/11 attacks. To some degree, a similar pattern has also impacted the number of events reported in later years, when the attention of world media turned elsewhere.Footnote ¹⁶ The diagram clearly shows that a relatively high proportion of the total violent events reported in Afghanistan took place in one district—Kabul City. This could be explained both by the Taliban and Islamic State’s strategic decision to concentrate efforts on Kabul in order to destabilize the American-backed regime and the prevalence of international media in the city. The latter has since eased its reporting on the attacks that took place in the city (Kamran Bokhari, personal communication, August 17, 2021).

Figure 3 shows that, until 2001, there were no data available on the vast majority of districts. The districts for which data were available show a yearly total of several dozens of events. The sole exception is the district of Kabul that includes the Afghan capital. It shows an annual total of over 100 material conflict events even during these relatively calm years. Please note that the visualization method used has an inherent weakness: the legend of the heatmap is automatically adapted to the scale of events in each individual year. Therefore, a casual inspection may miss the differences in scales of number of events between years.

Figure 3. Annual number of material conflict events in districts, 1995–2020.Footnote ¹⁷ Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

From 2001 to 2017, the number of districts for which no data were available dropped considerably. After that, the trend seems to begin reversing. The lack of data could be interpreted either as evidence of the absence of attacks resulting in no reporting as there was nothing to report, an indirect result of the gradual advancing of the Taliban that prevented media reports, or a failure of local and international media to report from many regions about the ongoing violence. While the first option may seem counter-intuitive, it could result from the Taliban’s and Islamic State’s strategic decision to focus theirs attacks on certain regions they deemed crucial for destabilizing the American backed-regime (Kamran Bokhari, personal communication, 17 August 2021), that is, Kabul.

Figure 4 presents the aggregation at the next level of administrative unit—the province level. The visualization at the province level is very similar to that of the district level. The aggregation also led to very few provinces for which no data were available. These appeared more frequently in the early years and cease to appear after 2006. Similarly to the district level diagram, here too Kabul province stands out as the hottest spot, with Kandahar province as another notable location after 2001.

Description of the proposed methods

Yonamine (Reference Yonamine2013, p. 1) pursued to create a policy-relevant forecasting tool by relying on GDELT, which was released that same year. At that time, GDELT was the only dataset that met the five attributes he defined for “building nuanced predictions on a global scale: broad spatial coverage; density; geo-coding; accuracy; and future availability in real-time” (Yonamine, Reference Yonamine2013, p. 2). Moreover, GDELT also offered sub-state geo-coding that fit Yonamine’s (Reference Yonamine2013, p. 3) aim of presenting “the first study to ever use open-source, machine-coded event data to build forecasts of political violence at a sub-state level of geospatial aggregation.”

Due to resource limitations, he focused on “forecasting conflict in sub-state geospatial units in a single country” (Yonamine, Reference Yonamine2013, p. 3). Afghanistan was chosen for two reasons: it offered a rich and varied number of relevant events over a long time period; and a precedent that demonstrated the ability to implement a similar approach to study Afghanistan (Zammit-Mangion et al., Reference Zammit-Mangion, Dewar, Kadirkamanathan and Sanguinetti2012).Footnote ¹⁹ In practice, he built predictions 1 month in advance, with district-month (N = 317), province-month (N = 32), and country-month (N = 1) as units of analysis.Footnote ²⁰ These units reflect an ascending order of administrative units, with provinces aggregating districts and the country level aggregating provinces. Therefore, using these units of analysis provided Yonamine (Reference Yonamine2013, p. 3) with “a rudimentary test of the effects of geo-spatial aggregation on forecast accuracy.”

The core of his analysisFootnote ²¹ is a comparison of “forecasts of levels of material conflict one-month-in advance” using the ARFIMA model and a naïve model. The latter assumes that the current real-world level of violence at a given location is identical to that of the previous month. The former model, which is explained below, outperformed the naïve model in terms of forecasting accuracy; however, its performance relative to the naïve model decreased as geographical aggregation increased (Yonamine, Reference Yonamine2013, p. 3).Footnote ²² This validation approach is aligned with the advice provided by Cederman and Weidmann (Reference Cederman and Weidmann2017, p. 476) for assessing the added value of a given approach: “…analysts need to do a better job comparing their forecasts from complex prediction machinery to simple baseline models. In its purest form, such a baseline model simply predicts no change from the past.”

Choosing the ARFIMA model enabled Yonamine to use “univariate data comprised solely of the counts of material conflict events” (Yonamine, Reference Yonamine2013, p. 7). Other data structures could not be created as the long timeframe and level of analysis on Afghani districts made it impossible to find appropriate exogenous variables to combine with the GDELT data in order to predict conflict levels (Yonamine, Reference Yonamine2013, p. 8). Yonamine (Reference Yonamine2013, p. 1) therefore focused on measuring the accuracy of the models’ predictions, as he believed that to be the best way to assess whether a model reflects “a real-world data generating process, or simply fitting noise.”

Yonamine’s (Reference Yonamine2013) work may be seen as an early example of both the “predictive turn” in literature (Ward et al., Reference Ward, Greenhill and Bakke2010) and the growing focus on localized predictions. His emphasis on forecasting accuracy is also grounded in his interest to present a useful prediction tool for the variety of actors involved in humanitarian and conflict resolving work (Zammit-Mangion et al., Reference Zammit-Mangion, Dewar, Kadirkamanathan and Sanguinetti2012). Yonamine’s (Reference Yonamine2013, p. 9) decision to employ ARFIMA for the first time in order to predict political conflict drew upon the experience in other fields that demonstrated the model’s “ability to generate more accurate and consistent forecasts than other time-series models.”

The ARFIMA is a commonly used method to model a time series with long memory (Reisen et al., Reference Reisen, Abraham and Lopes2001, p. 3; Liu et al., Reference Liu, Chen and Zhang2017, p. 5). A useful way of understanding the meaning of “long memory” in this context is through its opposite—a Markov Chain: “Rather than Markov processes where the current state of a system is enough to determine its immediate future, the fractional Gaussian noise model requires information about the complete past history of the system” (Graves et al., Reference Graves, Gramacy, Watkins and Franzke2017, p. 437). The ARFIMA process is based on three parameters: p, q, and d. While p stands for the number of lags in the autoregressive part to be modeled and q for the moving average lags, d indicates the degree of integration of the time series and can take on any value between 0 (stationary) and 1 (integrated) (Box-Steffensmeier and Tomlinson, Reference Box-Steffensmeier and Tomlinson2000, p. 64). The ARFIMA model may be represented by the following equation:

$$ \Phi (B){\left(1-B\right)}^d{X}_t=\Theta (B){\varepsilon}_t $$

where $ \Phi (B) $ and $ \Theta (B) $ represent the autoregressive and moving average components with B as back-shift operator (i.e., lag) such that BXt = $ {X}_{t-1} $ . $ \left(1-B\right) $ is the difference operator $ {\nabla}^d\;\mathrm{equal}\ \mathrm{to}\;{\left(1-B\right)}^d, $ and $ {\varepsilon}_t\hskip0.24em $ an error term that is normally distributed with E(²t) = 0 and variance $ {\sigma}^2 $ (Box-Steffensmeier and Tomlinson, Reference Box-Steffensmeier and Tomlinson2000, p. 64; Reisen et al., Reference Reisen, Abraham and Lopes2001, p. 3).

Yonamine’s (Reference Yonamine2013) analytical strategy consisted of the following steps. First, he trained the model on an in-sample training set that included all the data between February 2001 and April 2008. Second, he ran an out-of-sample prediction for May 2008. Third, he added the prediction for May 2008 to the in-sample training set. Fourth, he trained the model again on the new in-sample training set (i.e., containing now data between February 2001 and May 2008). Fifth, he ran a prediction for June 2008. Next, he repeated the abovementioned steps “until a final prediction is made for April 2012… using a model trained on February 2001 through March 2012” (Yonamine, Reference Yonamine2013, p. 11). The present article replicated the general analytical strategy of Yonamine (Reference Yonamine2013) rather than its exact steps. This replication was based on a nested loop, containing two for-loops (one for calculating ARFIMA predictions and the other—naive predictions), which went through the data files of violent events in Afghanistan on the district, province, and country levels.

The predictions for both models were calculated using the “forecast” R package’s ARFIMA and naive functions, respectively (Hyndman and Khandakar, Reference Hyndman and Khandakar2008). The advantage of this ARFIMA function is that it estimates and sets the model’s parameters automatically. However, by using this function, the current article differed from Yonamine’s (Reference Yonamine2013) article, which used the “ARFIMA” R package (Veenstra, Reference Veenstra2012). In line with the original article, a month-district/province/country unit that was not assigned a value of a conflict event was associated with a “0” (Yonamine, Reference Yonamine2013, p. 7). For the first two of the three administrative unit levels—district and province—the following steps were taken. For the third level of administrative unit, that is, country, the workflow was somewhat different as there was only one data file.

The comparison that Yonamine (Reference Yonamine2013) conducted between the forecasting accuracy of ARFIMA and the naïve model required a suitable error or difference statistic, a measure that “can be used to compare model-produced estimates with independent, reliable observations” (Willmott and Matsuura, Reference Willmott and Matsuura2005, p. 79). His error statistic of choice was the mean absolute error (MAE), which is a common measure in literature (Chai and Draxler, Reference Chai and Draxler2014). MAE is a dimensioned measure of average performance error in the sense that “it expresses average model-prediction error in the units of the variable of interest” (Willmott and Matsuura, Reference Willmott and Matsuura2005, p. 79). It is also used to reflect average difference rather than error when “no set of estimates is known to be the most reliable” (Willmott and Matsuura, Reference Willmott and Matsuura2005, p. 79). Generally speaking, MAE sums up the absolute values of errors in a model and divides the results by n (Willmott and Matsuura, Reference Willmott and Matsuura2005, p. 80).

$$ \mathrm{MAE}\hskip0.35em =\hskip0.35em \left[{n}^{-1}\sum \limits_{i\hskip0.35em =\hskip0.35em 1}^n\left|{e}_i\right|\right] $$

Although the use of MAE is widespread, Yonamine (Reference Yonamine2013) implemented it in a unique manner due to his need to compare the results of multiple univariate time-series analyses with regard to three different units of analysis (i.e., month-district, month-province, month-country):

As part of the replication pursued, the present study adopted the use of MAE as an error statistic, employing it in the same fashion as Yonamine (Reference Yonamine2013).

Results and discussion

The first part of the current study replicated Yonamine’s (Reference Yonamine2013) analytical strategy using ICEWS data. Yonamine (Reference Yonamine2013, p. 3) argued that the ARFIMA model’s outperformance of the naïve model will also be reflected in a smaller MAE size. Figure 5 presents the current study’s MAE results of ARFIMA and naïve models at the district level.

Figure 5 confirmed Yonamine’s (Reference Yonamine2013) assumption—the ARFIMA’s MAE, presented in red, is overall lower than those of the naïve’s MAE, presented in green. The five intersections of the two lines visualized the few exceptions: August 2008, January 2009, April 2010, March 2011, and September 2011. Next, Figure 6 presents the comparable results at the province level.

Figure 4. Annual number of material conflict events in provinces, 1995–2020.Footnote ¹⁸ Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

As shown, the ARFIMA model’s MAE results (i.e., red line) are lower than those of the naïve model (i.e., green line) at the province level too. Six intersections, indicating the months at which the naïve results are greater than those of ARFIMA, may be observed: August 2008, September 2009, April 2010, February 2011, March 2011, and September 2011. Figures 5 and 6 thus provide support for Yonamine’s (Reference Yonamine2013) assumptions that the ARFIMA MAE would be smaller than the naïve’s, and that the former’s performance relative to the latter’s will deteriorate the higher the level of aggregation is.Footnote ²⁵ However, the rate of deterioration observed was miniscule compared to the original study. Next, Figure 7 provides the data at the country level.

At the country level, presented in Figure 7, the rate at which the ARFIMA model outperformed the naïve model deteriorated substantially. The 48 month-country units were divided almost equally between the ARFIMA and naïve models—25 and 23 months, respectively. The aggregation of the data at the country level also provided an opportunity to compare the observed (i.e., real events) and the predictions by both ARFIMA and naïve models for the TS period—May 2008 to April 2012. These results are presented as a line graph in Figure 8.

As expected, the predictions by the naïve model, marked here by the dark blue line, constituted a delayed version of the actual data. In turn, the ARFIMA predictions successfully captured the general trends from early 2009 to late 2010, and again from February 2012. As the country level presented the worst performance by ARFIMA compared to the naïve model, an additional visualization was provided for the district level, that is, the level at which the ARFIMA model performed best. Therefore, Figure 9 presents a comparison between the observed and predicted results for the Kabul district—the one with the highest number of events per year.

Figure 5. Assessing accuracy at the district level.Footnote ²³ Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

As can be seen, the behavior of the naïve model in Figure 9 is similar to the one displayed in Figure 8, that is, at the country level. In contrast, the performance of the ARFIMA model was much better at this level than at the country level. In other words, for the most part, it successfully predicted the trend in the observed data. This finding may be seen as support not only for Yonamine’s (Reference Yonamine2013) assumptions but also for the argument in the forecasting literature whereby predictions may be most accurate for localized predictions.

In the next section, the results of the present study are compared to those of Yonamine (Reference Yonamine2013) to provide a comparison of the use of a shared analytical strategy with two main data sources—GDELT and ICEWS. The comparison is presented in Table 1.

Table 1. A comparison of the MAE results of Yonamine (Reference Yonamine2013) and the current study

Data source: Yonamine (Reference Yonamine2013) and Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Abbreviation: AE, ARFIMA error; MAE, mean absolute error; NE, naïve error.

Table 1 shows that, at the district level, Yonamine’s (Reference Yonamine2013) results were clearly better, with 47 out of 48 months for which the ARFIMA model outperformed the naïve model. In contrast, for the current study, the figure was just 43 out of 48 months. The situation is reversed at the province level, with 42 out of 48 months for the current study, and 40 out of 48 months for Yonamine (Reference Yonamine2013). This was contrasted once more at the country level, at which the figures for Yonamine (Reference Yonamine2013) and the current study were 30 out of 48 and 25 out of 48, respectively. An additional comparison of the MAE results obtained by Yonamine (Reference Yonamine2013) and the present study is provided in Figures 10–12 for the district, province, and country levels, respectively.

Figure 6. Assessing accuracy at the province level.Footnote ²⁴ Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Both Yonamine’s (Reference Yonamine2013) predictions and those made in the current study seem to follow similar trends. However, the former set’s trends are more similar to each other, with two exceptions: May 2009–October 2009 and November 2010–April 2011. What is also noticeable is the difference in scale between the two sets. Yonamine’s (Reference Yonamine2013) values for ARFIMA and naïve MAE range from 1.66 to 5.5 and 1.7 to 6.25, respectively. In contrast, the values for the current study are 0.88–1.97 and 1.04–2.21, respectively. The MAE results for the province level are provided in Figure 11.

Figure 7. Assessing accuracy at the country level.Footnote ²⁶ Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

The abovementioned difference in scale was more noticeable at the province level. For Yonamine (Reference Yonamine2013), the values of MAE ranged from 6.91 to 93.09 and 10.38 to 91.66 for the ARFIMA model and naïve model respectively. In contrast, the values for the current study ranged from 3.08 to 13.43 and 5.08 to 17.32, respectively. The difference probably originated in the different data sources, that is, GDELT and ICEWS, respectively. Moreover, while both sets of predictions seem to follow the same respective trends, Yonamine’s ARFIMA and naïve predictions tend to be more in sync.

Figure 12 shows both sets of the ARFIMA and naïve models as less in sync than at the previous levels. However, the original study’s sets were more closely related despite involving greater divergence and fluctuations. The increased scale of difference between the original and current studies probably resulted from the further aggregation of data. An additional assessment of the prediction accuracy was made by evaluating the extent to which the ARFIMA model reduced the MAE size compared to that of the naïve model. This measure was calculated using the following equation:

$$ 100-\frac{AE\times 100}{NE} $$

where AE stands for “ARFIMA error” and NE stands for “naïve error.” The results are summarized in Table 2.

Figure 8. Comparison of observed, ARFIMA predictions, and naïve predictions at the country level. Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Table 2. A comparison of the reduction in MAE size

Data source: Yonamine (Reference Yonamine2013) and Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

The results presented in Table 2 support the findings shown in Figures 10–12. The proportion of the ARFIMA model’s outperformance of the naïve model was better at the district level in the original study. In the original study, the ARFIMA model reached an MAE size that was 16.33% smaller than that of the naïve model. The comparable figure for the current study at that administrative level was 14.94%. The situation was reversed at the province level, for which the current study reached a better result than that of the original study—19.57% compared to 12.77% in the original study. For both studies, the AFRIMA model’s performance was the worst at the country level, at which the proportion of reduction in MAE size was the smallest for both studies—1.05% in the original study and 9.37% in the current one.

The results presented so far called for a qualification of Yonamine’s (Reference Yonamine2013) assumption that the ARFIMA model’s performance comparing to that of the naïve model deteriorates with each level of aggregation. This seemed to be true for the highest level of aggregation but not necessarily for the interim one in the current study. Moreover, the rate of deterioration in the ARFIMA model’s performance compared to that of the naïve model was significantly smaller on all three levels of administrative units than in the original study.

Furthermore, with regard to the difference in scales mentioned above, it should be noted that, because the MAE is based on error size, which, in turn, is determined by the subtraction of the observed from the predicted in absolute values, this finding may suggest that Yonamine’s (Reference Yonamine2013) study contained a higher number of cases per month-district units. That would be in line with a common observation in the literature that his data source, GDELT, may contain a considerable number of duplicated events and thus suffers from a high number of false positives. This may also help to explain the small difference between the results obtained by the current study at the district and province levels—reflected in the number of administrative unit month for which the naïve model outperformed the ARFIMA model—which were very close: 43 versus 5 and 42 versus 6, respectively. The similarity between these results was also reflected in the much smaller difference in scale of the results compared to the original study.

The previous two sections of the analysis helped to assess the usability of Yonamine’s (Reference Yonamine2013) analytical strategy with ICEWS data. Having done so, the approach was employed on the entire ICEWS dataset timeframe—January 1995 through August 2021. The significantly longer period added yet another dimension for evaluating Yonamine’s (Reference Yonamine2013) approach when using the ICEWS data; however, it required the identification of a suitable cutting point for the data, dividing it into an ITS and TS. Three cutting points for sets of ARFIMA and naïve predictions at the country level were therefore determined: 2/3 ITS—1/3 TS, ½ ITS—½ (TS), and ¾ ITS—¼ TS. The country level was selected under the assumption that it was at that level that the ARFIMA model’s performance is the worst. Therefore, any model that performed better at this level would do even better at the other levels. The results obtained by this step are presented in Table 3.

Table 3. A comparison of predictions at the country level

Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021). Abbreviations: AE, ARFIMA error; ITS, initial training set; MAE, mean absolute error; NE, naïve error; TS, test set.

Due to the very close “accuracy rate” measurements for the first two upper sets, a further comparison was conducted at the district level. As mentioned above, this level is assumed to yield the best results in terms of the ARFIMA model outperforming the naïve one. The results of the comparison are presented in Table 4.

Table 4. A comparison of predictions at the district level

Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Abbreviations: AE, ARFIMA error; ITS, initial training set; MAE, mean absolute error; NE, naïve error; TS, test set.

The results of this comparison indicate that, at the district level, the performance of the ARFIMA model was better in the upper set of the two models than the lower one for both the accuracy rate and proportion of reduction in MAE size. Therefore, the next step of the analysis was to focus on a comparison of the results of the ARFIMA and naïve models for the division of the dataset into equal sized ITS and TS. The results for all three levels of administrative units are presented in Table 5.

Table 5. A comparison of predictions with a cutting point at ½ full timeframe

Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Abbreviation: AE, ARFIMA error; MAE, mean absolute error; NE, naïve error.

Table 5 contains somewhat surprising results. For the original timeframe, the use of the ARFIMA model on ICEWS data resulted in a contradiction with Yonamine’s (Reference Yonamine2013) results in terms of the reduction in MAE size. As shown in Table 2, the performance of the ARFIMA model yielded better results at the province level than at the district level, while in the original study, the latter provided the best results. However, using the division of the entire dataset into two equal sized sets, the ARFIMA model’s outperformance of the naïve model met the original study’s expectations as measured by reduction in MAE size: the results at the district level were the best and the outperformance rate deteriorated the higher the level of aggregation. The same can also be seen in Figures 13–15, which show a comparison of the accuracy rate of both ARFIMA and naïve models as measured in MAE across the three administrative units. Figure 13 provides an overview of the results at the district level.

Figure 9. A comparison of observed, ARFIMA predictions, and naïve predictions for the Kabul City district. Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Figure 13 shows the red line, representing the MAE results for the ARFIMA model, as consistently below the green line, which represents the MAE of the naïve model, almost throughout the entire duration of the TS. It provides a visual demonstration of the 85% accuracy rate mentioned in Table 5. Similarly, the not much worse results obtained for the province level are shown in Figure 14.

Figure 10. A comparison of accuracy assessments between Yonamine (Reference Yonamine2013) and the current study at the district level. Legend: original, Yonamine (Reference Yonamine2013); current, current study; AE, ARFIMA error; NE, naïve error. Data source: Yonamine (Reference Yonamine2013) and Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Finally, the significant deterioration in the ARFIMA model’s outperformance of the naïve model is visually noticeable in Figure 15.

Figure 11. A comparison of accuracy assessments between Yonamine (Reference Yonamine2013) and the current study at the province level. Legend: original, Yonamine (Reference Yonamine2013); current, current study; AE, ARFIMA error; NE, naïve error. Data source: Yonamine (Reference Yonamine2013) and Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Figure 12. A comparison of accuracy assessments between Yonamine (Reference Yonamine2013) and the current study at the country level. Legend: original, Yonamine (Reference Yonamine2013); current, current study; AE, ARFIMA error; NE, Naïve error. Data source: Yonamine (Reference Yonamine2013) and Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Figure 13. An accuracy assessment with a cutting point at ½ of the full timeframe—district level. Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Figure 14. Accuracy assessment with cutting point ½ of the full timeframe—province level. Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

Figure 15. Accuracy assessment with cutting point ½ of the full timeframe—country level. Data source: Lockheed Martin Advanced Technology Laboratories (ATL) (2021).

As mentioned in the discussion of the second section, the difference in results between the original and current studies probably originates from their respective reliance upon GDELT and ICEWS, respectively. This also led to the smaller number of cases per administrative unit months characteristic to ICEWS in the current study. Therefore, it is reasonable to assume that the aggregation of the district-level data into the province level in the current study resulted in better performance than displayed at the district level in the original timeframe, before the deterioration at the (too-) aggregated country level. It does, however, seem that the longer duration of the last section provided the ARFIMA model with enough data at the ITS to yield better performance in spite of the smaller number of cases per administrative unit month in the ICEWS data.