Observations of tropical cyclones reveal high-gradient shock-like structures in its boundary layer. Williams et al. (2013) proposed an axisymmetric slab boundary layer model with a u ∂u/∂r term which is capable of simulating such shock-like structures. In order to simulate the shock structures most accurately, study the numerical shock capturing methods WENO5 (Weighted Essentially Non-Oscillatory fifth-order), CRWENO5 (Compact Reconstruction WENO5) and CRWENO5-LD (CRWENO5-Low Dissipation). We compare these methods with a fourth-order finite difference scheme and with the Fourier spectral method. We also study their convergence behavior and conservations of physical quantities in the two dimensional ideal flow field. The boundary layer model of Williams et al. (2013) is formulated assuming axisymmetry. However, observational evidence suggests that the shock-like structures found in the boundary layers of real tropical cyclones can far from axisymmetric. Here, we transform the axisymmetric slab boundary layer model of Williams et al. (2013) to Cartesian coordinates and couple it with shallow water model in order to study asymmetric shock-like structures in the boundary layer of a tropical cyclone. We find that large updrafts occur in the region of large inertial instability of tropical cyclones with single eyewall. This may indicate that updrafts associated with shock-like structures play an important role in the intensification of tropical cyclones with a single eyewall. In our experiments with concentric eyewall, we found weaker updrafts at the inner eyewall and stronger downward motion in the moat region for a smaller moat size. Since this study employs a dry model, the results indicate that shock-like structures in the boundary layer also tend to intensify the outer eyewall and weaken the inner eyewall. In the other experiment, we found that the vorticity structure inside the core vortex of a concentric eyewall structure significantly affects the vertical velocity distribution at the inner and outer eyewalls. The results in this study indicate that not only thermodynamic processes but also shock-like structures associated with dynamical processes would significantly affect structures and intensity of tropical cyclones.