update reactive power note

docs/src/formulation_library/Branch.md

@@ -1,7 +1,7 @@
 # `PowerSystems.Branch` Formulations
 
 !!! note
-    The usage of reactive power variables and constraints will depend on the network model used, i.e. if it uses (or not) reactive power. If the network model is purely active power based, then no variables and constraints related to reactive power are created. For the sake of completion, if the formulation allows the usage of reactive power it will be included.
+    The use of reactive power variables and constraints will depend on the network model used, i.e., whether it uses (or does not use) reactive power. If the network model is purely active power-based, reactive power variables and related constraints are not created.
 
 ### Table of contents
 

docs/src/formulation_library/Load.md

@@ -3,7 +3,7 @@
 Electric load formulations define the optimization models that describe load units (demand) mathematical model in different operational settings, such as economic dispatch and unit commitment.
 
 !!! note
-    The usage of reactive power variables and constraints will depend on the network model used, i.e. if it uses (or not) reactive power. If the network model is purely active power based, then no variables and constraints related to reactive power are created. For the sake of completion, if the formulation allows the usage of reactive power it will be included.
+    The use of reactive power variables and constraints will depend on the network model used, i.e., whether it uses (or does not use) reactive power. If the network model is purely active power-based, reactive power variables and related constraints are not created.
 
 ### Table of contents
 

docs/src/formulation_library/RenewableGen.md

@@ -3,7 +3,7 @@
 Renewable generation formulations define the optimization models that describe renewable units mathematical model in different operational settings, such as economic dispatch and unit commitment.
 
 !!! note
-    The usage of reactive power variables and constraints will depend on the network model used, i.e. if it uses (or not) reactive power. If the network model is purely active power based, then no variables and constraints related to reactive power are created. For the sake of completion, if the formulation allows the usage of reactive power it will be included.
+    The use of reactive power variables and constraints will depend on the network model used, i.e., whether it uses (or does not use) reactive power. If the network model is purely active power-based, reactive power variables and related constraints are not created.
 
 !!! note
     Reserve variables for services are not included in the formulation, albeit their inclusion change the variables, expressions, constraints and objective functions created. A detailed description of the implications in the optimization models is described in the [Service formulation](@ref service_formulations) section.

docs/src/formulation_library/ThermalGen.md

@@ -8,7 +8,7 @@ Thermal generation formulations define the optimization models that describe the
 
 
 !!! note
-    The usage of reactive power variables and constraints will depend on the network model used, i.e. if it uses (or not) reactive power. If the network model is purely active power based, then no variables and constraints related to reactive power are created. For the sake of completion, if the formulation allows the usage of reactive power it will be included.
+    The use of reactive power variables and constraints will depend on the network model used, i.e., whether it uses (or does not use) reactive power. If the network model is purely active power-based,  reactive power variables and related constraints are not created.
 
 !!! note
     Reserve variables for services are not included in the formulation, albeit their inclusion change the variables, expressions, constraints and objective functions created. A detailed description of the implications in the optimization models is described in the [Service formulation](@ref service_formulations) section.