genneth said:Strong coupling is whenever a perturbative expansion fails to converge.
Parlyne said:By this definition, all interacting quantum field theories would be strongly coupled, since the radius of convergence in coupling constant space is always strictly zero. (There is always at least one coupling constant which must have a positive real part.)
Strong coupling is the situation where the assumptions going into the perturbation expansion break down. This essentially means that the potential energy involved in the interaction should is not small compared to the kinetic plus rest energy.
Haelfix said:Said another way, the dimensionless parameter (coupling constant or other) that you use to perturb around is of order 1. So for instance QCD's coupling (which is a function of energy) becomes of order 1 in the IR and you can no longer rely on perturbation theory.
In a system, strong coupling refers to a situation where the components or parts of the system are highly interconnected and dependent on one another. This means that changes in one component can greatly affect the behavior and functioning of other components in the system.
Strong coupling is characterized by tight connections and high interdependence between system components, while weak coupling means looser connections and less dependence between components. In a strongly coupled system, changes in one component can have a significant impact on the entire system, while in a weakly coupled system, changes in one component may not affect the others as much.
Strong coupling allows for efficient communication and coordination between components, leading to faster processing and improved performance. It also allows for better error detection and handling, as issues in one component can be quickly identified and addressed before they cause problems in other parts of the system.
One of the main drawbacks of a strongly coupled system is that it can be difficult to make changes or updates to individual components without affecting the entire system. This can make it challenging to maintain and update the system over time. Additionally, if one component fails, it can potentially cause a cascading failure in other components, leading to system-wide issues.
There are a few strategies that can be used to manage or reduce strong coupling in a system. One approach is to use design patterns and principles that promote loose coupling, such as the use of interfaces and decoupling layers. Another option is to use communication protocols that allow for more flexibility and autonomy between components. Additionally, regularly reviewing and refactoring the system architecture can help identify and address areas of strong coupling.