Engineered solid binding peptides can be used as molecular tools for a variety of bio/nanotechnology applications, especially in interfacing biology with solid-state devices at bio/nano soft interfaces. The control of surface organization, and therefore peptide-solid interactions, is critical and involves surface phenomena such as binding, surface diffusion, and self-organization on atomically flat solids. Each of these phenomena requires the knowledge of peptide’s folding patterns which are, however, difficult to study both experimentally and computationally. Molecular dynamics, MD, has been used to computationally model peptide/solid interactions, but without information regarding the energy landscape of peptide conformations the challenge of predictive design remains. While several methods exist for finding the energy landscapes of single peptide systems, currently no approach handles multi-peptide/surface systems. Here we use Time-Varying Autoregression with Low Rank Tensors, TVART, to efficiently explore the energy landscapes of such systems, aiming to find accurate linear approximations for predictive design of peptides at bio/nano interfaces. Using TVART, with each slice representing a discrete time window, allows for temporal smoothness and high predictive accuracy. It is anticipated that some descriptions of conformation will be better suited to describe peptide conformation energy landscapes than others; based on this premise, we examined interatomic distances/adjacencies and peptide backbone torsion angles as descriptions of peptide conformation. Through such analyses, it is becoming possible to describe how peptide conformations in multi-peptide/surface systems evolve through the energy landscape and settle into energy minima (stable conformations). These conformations can then be corroborated with experimental validation of peptide self-organization on the surface using scanning probe microscopy techniques with sub-A resolutions. The combination of computational modeling and high-resolution experiments is expected to aid predictive design platforms for future applications in biosensors, bioelectronics, and logic devices.