Poggiolini, P. et al. The GN model of fiber non-linear propagation and its applications.
A random walk coefficient (RWC) prediction model is developed using a radiation-induced attenuation model of fiber and a RWC expression.
Recently, a new model of fiber architecture of the linea alba has been described consisting of an oblique fiber layer of intermingling oblique fibers, a transverse fiber layer containing mainly transverse fibril bundles, and a variable, small irregular fiber layer.
A physical meaning to the phenomenological law is proposed via a simple model of fiber rupture in single-fiber-reinforced composite.
A random walk coefficient (RWC) prediction model of interferometric fiber optic gyroscope (IFOG) in radiation environment has been developed, combining a radiation-induced attenuation (RIA) model of fiber and a RWC expression of digital closed-loop IFOG, and verified by the radiation experiments results of two fiber coils and an experimental IFOG.
To circumvent these difficulties, we present a two dimensional kinematic multi tendon-string EA model of fiber slackness and tautness through IP motion, including the retinacular and oblique retinacular EA ligaments.
Monotonic stress strain relationship of actively-confined concrete has been used as the base model to establish analysis-oriented stress strain model of fiber reinforced polymer (FRP) confined concrete.
In this study, a stress-strain model of fiber-reinforced polymers (FRPs -confined concrete based on the lateral conFRPs -confinedness was adopted to simulate the lateral response of Rconcretes retrofitted with external FRP jackets and tested under axial and lateral loads.
Moreover, considering the neighboring CNTs' tunneling effect, we modeled CNTs as 'hard-core' objects instead of the so-called 'soft-core' model of fiber [15] to deal with both tensile and compressive strains on nanocomposites, with the assumption of non-penetration between the CNTs.
S. Kim et al. investigated muscle architecture throughout the volume of the supraspinatus muscle by using three-dimensional model of fiber bundle architecture within the anterior and posterior regions of pathologic supraspinatus muscle.
It allows simultaneous modeling of fibers and related matrice portions, entire layers and whole multilayers.
