As an angler I have always been fascinated by the hydrodynamic environment of riparian habitat – an environment that for the entire life of resident fish is constantly flowing by them and churning over structures of the riverbed. How fish negotiate this turbulence is of profound intellectual interest as well as conservation value. In order to address how and why fish positioning occurs where it does along the length of the river, collaborators (Universities of Florida and Montana) and I quantified the swimming behavior of rainbow trout refuging within a range of eddy sizes, which are backward flowing regions of water where fish are able to escape the fast free-stream water velocity (Figure 4). In addition, we collected flow field data and were able to show that trout preference for refuging depends on the size and nature of that refuge – preference to swim in reduced flow does not always equal capacity to capitalize if the flow regime does not support the biomechanics of swimming. This study is applicable to the design of fish ladders (diversions through which migrating fish must successfully pass to breach dams) and which have on the order of single-digit percentage passage success for anadromous fishes, such as the steelhead, sturgeon or lamprey. Further directions seek to expand this research question to other fish species, test fish over a greater range of flow speeds and increase the complexity of turbulence, in an effort to get at more real-world picture of natural flow regimes and more relevant fish behavior and biomechanics.