How Hot Spot Analysis Comparison works

Exclude nonsignificant features

When the hot spot results are dominated by a single category such as in the examples above, it is most common for it to be the nonsignificant category. However, if the nonsignificant features are not of research interest, you may not want the similarity and kappa values to simply reflect the abundance of nonsignificant areas in both results. To prevent this, you can use the Exclude Nonsignificant Features parameter to exclude any pair of corresponding features from the comparisons if both hot spot results are not statistically significant. If excluded, the tool calculates conditional similarity and kappa values that compare only the statistically significant hot and cold spots to accurately reflect their similarity and association. The counts and overall proportions of the significance level categories impact the similarity and kappa values, so consider the outcome before excluding large numbers of nonsignificant features.

Category similarity

There are seven possible significance level categories in each hot spot result. The categories have a natural ordering from 99% hot to 99% cold, and some categories are more similar to each other than others. Category similarity weights allow you to define how similar you consider the different significance level categories to be. Each combination of results (for example, 90% cold versus 95% hot) must have a category weight between 0 and 1 indicating their similarity. Combinations with weights equal to 1 are considered exact matches, and combinations with weights equal to 0 are considered completely dissimilar. Values between 0 and 1 indicate degrees of partial similarity between the categories. The weights must be symmetric; for example, the weight between 99% hot and 95% hot must be equal to the weight between 95% hot and 99% hot.

If two categories have a similarity weight equal to 1, the calculations of similarity and association will treat them as if they are the same category, so you can use the weights to combine different categories. For example, to perform the two hot spot analyses at a 95% confidence level, you can combine the 90% cold, not significant, and 90% hot categories using a weight equal to 1 for all combinations of the categories. The similarity values and kappa values will treat 90% cold and 90% hot categories as if they are not significant. Additionally, if you exclude nonsignificant features, any categories combined with the not significant category will also be excluded.

You can also reverse hot and cold relationships by giving large weights between hot and cold spots. Reversing relationships is recommended when the hot spot results have a negative relationship, such as cold spots of median income aligning with hot spots of diabetes.

The category similarity weights are specified using the Similarity Weighting Method parameter. The following options are available:

• Fuzzy weights—Similarity weights are fuzzy (nonbinary) and determined by the closeness of significance levels. All hot spots are completely dissimilar to all cold spots and nonsignificant features (and vice versa). The weights between 90%, 95%, and 99% hot and cold spots are determined by ratios of critical values of upper one-sided rejection regions of the normal distribution; for example, the weight between 95% hot and 99% hot is 1.645/2.33 = 0.71. See the first image in the Weight matrix pop-out section below for all other weights between the categories. This is the default.
• Exact significance level matching—Features must have the same significance level to be considered similar. For example, 99% hot spots will be considered completely dissimilar to 95% and 90% hot spots.
• Combine 90%, 95%, and 99% significant—Features that are 90%, 95%, and 99% hot spots will be considered perfectly similar to each other, and all features that are 90%, 95%, and 99% cold spots will be considered perfectly similar to each other. This option treats all features at or above 90% significance as being the same (statistically significant) and all features below 90% confidence as being the same (nonsignificant).
• Combine 95% and 99% significant—Features that are 95% and 99% hot spots will be considered perfectly similar, and features that are 95% and 99% cold spots will be considered perfectly similar. For example, 90% hot and 90% cold spots will be considered completely dissimilar to higher significance levels. This option treats all features at or above 95% significance as being the same (statistically significant) and all features below 95% significance as being the same (nonsignificant).
• Use only 99% significant—Only features that are 99% hot (or cold) spots will be considered perfectly similar to each other. This option treats all features below 99% significance as being nonsignificant.
• Reverse hot and cold relationships—The default fuzzy weights will be used, but hot spots of the first hot spot result will be considered similar to the cold spots of the second hot spot result. For example, 99% hot spots in one result will be considered perfectly similar to 99% cold spots in the other result and partially similar to 95% and 90% cold spots in the other result.
• Get weights from table—Weights defined by fields of a table layer will be used. The table is provided in the Input Weights Table parameter and must contain CATEGORY1, CATEGORY2, and WEIGHT fields. Provide the significance level categories of the pair (the Gi_Bin field values of the input layers) in the category fields and the similarity weight between them in the weight field. For example, the [-3, -2, 0.6] row assigns the similarity weight value 0.6 to the 99% cold versus 95% cold combination. If a combination is not provided in the table, the weight is assumed to be 0. The table can be exported from the weight matrix pop-out.
• Custom weights—Custom similarity weight values provided in the Category Similarity Weights parameter will be used.

Weight matrix pop-out

The Category Similarity Weights parameter allows you to interactively view and edit the weights using a weight matrix pop-out. The displayed weights update as you choose different options of the Similarity Weighting Method parameter, so you can see the weights associated with each option and make any edits. To open the pop-out, click the Custom button next to the parameter.

To assign a custom weight between a significance level combination, click the associated cell, type the weight value between 0 and 1, and press Enter. To keep the weights symmetric, you can only edit cells in the lower left half of the matrix, and the weight will be mirrored to the equivalent cell on the upper right. The following image shows an example of custom weights that use exact significance level matching with reversed hot and cold relationships (for example, 95% hot is perfectly similar to 95% cold and completely dissimilar to all other significance levels):

After providing the weights, click OK or click outside the pop-out to apply the weights. If any weights were altered, the Similarity Weighting Method parameter value will change to Custom weights. You can also click Cancel or the Close button to close the pop-out and not apply the changes.

The Export button opens a browse dialog box that allows you to save the weight values as a table so that they can be reused later with the Get weights from table option. To reuse custom weights in the future, it is recommended that you create the weight file using the weights matrix pop-out; then use the weights table for future comparisons.

Distance similarity

In addition to categorical similarity, distance similarity allows partial matches when the features do not have the same significance level but other features in their neighborhood do have matching significance levels. Because hot spot analysis is a spatial method that uses local neighborhoods, the significance level of each feature is a characterization of the values of the feature and its closest neighbors, not just of the feature. In this sense, if any neighboring features are similar, they should contribute somewhat to the similarity of their neighbors.

The Number of Neighbors parameter specifies the number of additional neighboring features that will be used in the comparisons, and partial similarity is incorporated using a distance weight based on the ordering of the neighbors. The feature receives a distance weight equal to 1, and the weights decrease consistently for each additional neighbor using the following formula:

The rank in the formula is the order of the neighbors and ranges from 0 (for the feature being compared) up to the number of neighbors (for the farthest neighbor). For example, with four neighbors (five, including the feature being compared), the following five distance weights are used: 5/5 (1), 4/5 (0.8), 3/5 (0.6), 2/5 (0.4), and 1/5 (0.2).

Geoprocessing messages

The messages display information about global comparisons between the hot spot results. The messages display the following information:

• Similarity Value—A value between 0 and 1 measuring the overall similarity between the hot spot result layers. The value can be interpreted as a fuzzy probability that any pair of corresponding features have the same significance level category. The value is equal to the average of all local similarity values.
• Expected Similarity Value—The expected value of the similarity under the assumption that the two hot spot result layers are unassociated (independent). If the similarity value is larger than its expected value, this suggests an underlying dependence between the two maps. The value is mostly informational and is used to scale the similarity value when calculating the kappa value. The value is equal to the average of the local expected similarity values.
• Spatial Fuzzy Kappa—A measure of the association between the hot spot analysis variables that is calculated by scaling the similarity value by its expected value. Hot spot results that are perfectly associated will have the value 1, and unassociated (independent) results will have a value close to 0. Negative values indicate a negative relationship between the hot spot analysis variables. While the value has no lower bound, the values are rarely less than -3 in practice. There are no strict rules for interpreting kappa values, but common recommendations are to interpret values above 0.8 as almost perfect association, values between 0.6 and 0.8 as strong association, values between 0.4 and 0.6 as moderate association, values between 0.2 and 0.4 as fair association, values between 0 and 0.2 as slight association, and negative values as no association (or negative association for large negative values).
• Number of Nonsignificant Features—The number of hot spot significance level pairs in which both features are not statistically significant.

  Note:

  If nonsignificant features are excluded, they will not be included in the similarity, expected similarity, or spatial fuzzy kappa calculations. The labels will change to Conditional Similarity Value, Conditional Expected Similarity Value, Conditional Spatial Fuzzy Kappa, and Number of Excluded Nonsignificant Features to indicate that the values are conditioned on statistically significant features.

• The Categorical Weights Table message table displays the category weights between each hot spot significance level pair. For example, the image below displays the categorical weight table for the default categorical similarity weighting method:

  

• The Hot Spot Significance Level Pair (Counts) message table display counts of each hot spot significance level pair. For example, in the image below, the value 440 in the first row and second column means that 440 feature pairs were 99% cold in the first hot spot result and 95% cold in the second result. The row and column totals in the margins indicate the total counts of each significance level among each hot spot result.

  

• The Hot Spot Significance Level Pair (Percentages) message table displays the same information as the counts table, but the counts are converted to percentages of the row total. For example, in the image below, the cell that displayed 440 in the image above now displays 5.57 (440/7904 = 0.0557). This table is especially useful when the two hot spot results represent the same variable measured at different times. In this case, the tables allow you to see how the categories transitioned in the time between the measurements. For example, the image below shows that among the features that were 99% cold spots in the first result, 89.26 percent stayed as 99% cold spots, 5.57 percent changed to 95% cold spots, and so on.

  

Output features and group layer

The output features will be the intersections of the input hot spot result layers and will contain fields summarizing the local similarity and association for each pair of corresponding features. The feature class will have the following fields:

• Hot Spot 1 Input Value (GI_BIN_1)—An integer representing the significance level category of the feature from the first hot spot result. The values range from -3 (99% cold) to 3 (99% hot). The field will be of type long.
• Hot Spot 2 Input Value (GI_BIN_2)—An integer representing the significance level category of the feature from the second hot spot result. The field will be of type long.
• Hot Spot 1 Significance Level (GI_SIG_1)—The significance level category of the feature from the first hot spot result. The possible values are: Cold 99%, Cold 95%, Cold 90%, Not Significant, Hot 90%, Hot 95%, and Hot 99%. The field will be of type text.
• Hot Spot 2 Significance Level (GI_SIG_2)—The significance level category of the feature from the second hot spot result. The field will be of type text.
• Similarity Value (SIM_VALUE)—The local similarity value of the feature pair. The value will be between 0 and 1. The field will be of type double.
• Expected Similarity Value (EXP_SIM)—The expected value of the similarity of the feature pair. The value will be between 0 and 1. The field will be of type double.
• Spatial Fuzzy Kappa (KAPPA)—The spatial fuzzy kappa value of the feature pair. The field will be of type double.
• Significance Level Combinations (CAT_PAIR)—The combination of significance level categories of the hot spot results. This field is used as the basis for the two charts below. The field will be of type text.

When the tool is run in a map, three layers will be added to a group layer that allow you to explore the similarity, association, and significance level pairs spatially. The first layer displays the similarity values classified into five equal intervals between 0 and 1, and lower similarity values are in darker colors to emphasize the areas that are most dissimilar. The second layer displays the spatial fuzzy kappa values symbolized with equal intervals and six classes. The third layer displays each significance level combination with custom symbology to identify features where one input hot spot result was a statistically significant hot spot and the other was a statistically significant cold spot (in the custom symbology, 90%, 95%, and 99% significance is not distinguished in order to reduce the number of combinations). By default, the first layer is enabled and the last two are disabled.

Charts

The final layer comes with two charts to further investigate the significance level combinations between the results. These charts display the same information as the tables in the messages, but the charts are colored by the counts and percentages for ease of interpretation. You can also use selections between the charts and map to, for example, select all features that were 99% hot spots in one result and 99% cold spots in the other result, indicating the largest possible differences.

The Hot Spot Significance Level Pair Counts heat chart displays counts of each significance level combination with deeper shades of blue for higher counts. For example, in the image below, the pairs with the largest counts were 99% cold to 99% cold (top-left), nonsignificant to nonsignificant (middle), and 99% hot to 99% hot (bottom-right).

The Hot Spot 2 Level Counts within Hot Spot 1 Level Categories bar chart displays stacked horizontal bars to visualize the counts of each significance level category of the second hot spot result within the categories of the first result. For example, in the image below, the vast majority of 99% hot and cold spots were also significant hot and cold spots (the top and bottom bars are mostly blue and red, respectively). However, among nonsignificant features in the first result, there were more matching hot spots than cold spots in the second result (the middle bar has more red than blue). If the two hot spot result layers represent temperatures measured at different times, this may indicate a general warming of the study area between the measurement times.

Similarity value calculation

Local similarity values are calculated for each pair of corresponding features in the hot spot analysis results. The global similarity value is the average of all local similarity values.

The similarity value for the feature pair will be equal to 1 when the corresponding features each have the same significance level category (or have categories that have been combined by similarity weights). The similarity value will be equal to 0 when all neighbors of the first result have completely dissimilar significance level categories as all neighbors of the second result (for example, all hot spots in the first result and all cold spots in the second result). All other situations will result in similarity values between 0 and 1.

For each pair of features, the similarity value involves calculating two directional similarity values and taking the smaller of the two. The first directional similarity is the similarity from the first result to the second, and the second directional similarity is from the second result to the first. The calculation for each entails comparing the category of the feature of one result to the corresponding feature of the other result and each of its neighbors. For the corresponding feature and each neighbor, the category weight is multiplied by the distance weight, and the largest result is the directional similarity value.

For example, the image below shows two hot spot results, A and B. A and B each have three features: one hot spot (red), cold spot (blue), and nonsignificant feature (light gray). The largest polygons are the first feature pair, the smallest polygons are the second feature pair, and the medium polygons are the third feature pair. The centroids of the polygons are shown to help determine which polygons are closer than others; the first polygon is slightly closer to the second polygon than it is to the third polygon.

For this example, assume that the category weight between matching categories (hot to hot, cold to cold, and nonsignificant to nonsignificant) is 1, the weight between hot and cold spots is 0, and nonsignificant features have weight 1/2 with both hot and cold spots.

The following table shows the category weights, distance weights, and similarity of the directional similarity from the result A to result B. The similarity value in the last column is calculated by multiplying the distance weight and category weight:

The largest similarity from result A to result B is 0.33, which occurs for two neighbor combinations. The following table shows the directional similarity from result B to result A.

The largest similarity from result B to result A is 0.67.

The local similarity value for the feature pair is the smaller of the two directional similarities (A to B and B to A), so the similarity value of the first feature pair is 0.33. The same procedure is also used to calculate the similarity value for the second and third feature pairs, and for this example, both have similarity values equal to 0.5. The global similarity value is the average of the similarity values of all feature pairs, and for this example, the global similarity value is 4/9 = 0.44.

If nonsignificant features are excluded, their similarity values will not calculated, and they will not be included in the average for the global similarity value; however, they will still be used as neighbors when calculating the similarity value of features that are not excluded.

Expected similarity value calculation

For each feature, the calculation of the expected similarity value uses the same procedure as the similarity value; however, the feature of the first result is paired with random features in the second result rather than its corresponding feature.

By comparing random neighborhoods, the expected value accounts for category frequency (more common categories are more likely to be randomly chosen) and category clustering within the neighborhoods (the random neighborhoods are likely to contain clusters of features with similar significance level categories). The similarity value from each random pairing is a single estimate of the similarity value under the assumption that the two hot spot results are independent. To calculate the expected similarity value of a feature, each feature of the first result is paired with many random neighbors, and the random similarity values are averaged. The Number of Permutations parameter specifies the number of random pairings for each feature. Larger numbers of permutations will increase the run time of the tool and increase the precision of the expected similarity and kappa values.

The global expected similarity value is the average of the expected similarity values of all feature pairs. If nonsignificant features are excluded, the excluded features will never be chosen as random neighbors, and their expected similarity value is not calculated; however they can still be included as neighbors of the randomly selected features.