80   CeedScalar U_infty = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));  in BlasiusSolution()
91   CeedScalar Y[5];  in BlasiusSolution()  local
92   Y[1] = U_infty * f[1];  in BlasiusSolution()
93   Y[2] = 0.5 * sqrt(nu * U_infty / (x0 + x[0] - x_inflow)) * (eta * f[1] - f[0]);  in BlasiusSolution()
94   Y[3] = 0.;  in BlasiusSolution()
95   Y[4] = S_infty.Y.temperature * h[0];  in BlasiusSolution()
96   Y[0] = rho_infty / h[0] * Rd * Y[4];  in BlasiusSolution()
97   return StateFromY(&blasius->newtonian_ctx, Y);  in BlasiusSolution()
115   const CeedScalar U_infty = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));  in ICsBlasius()
143   const CeedScalar               U_infty     = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));  in Blasius_Inflow()
163       s.Y         = StatePrimitiveFromConservative(gas, s.U);  in Blasius_Inflow()
166       s.Y         = StatePrimitiveFromConservative(gas, s.U);  in Blasius_Inflow()
200   const CeedScalar               U_infty     = sqrt(Dot3(S_infty.Y.velocity, S_infty.Y.velocity));  in Blasius_Inflow_Jacobian()
218       CeedScalar dE_internal = drho * gas->cv * S_infty.Y.temperature;  in Blasius_Inflow_Jacobian()
219       CeedScalar dE_kinetic  = .5 * drho * Dot3(s.Y.velocity, s.Y.velocity);  in Blasius_Inflow_Jacobian()
221       dP                     = drho * Rd * S_infty.Y.temperature;  // interior rho with exterior T  in Blasius_Inflow_Jacobian()
229     const CeedScalar u_normal = Dot3(norm, s.Y.velocity);  in Blasius_Inflow_Jacobian()
233       v[j + 1][i] = -wdetJb * (drho * u_normal * s.Y.velocity[j] + norm[j] * dP);  in Blasius_Inflow_Jacobian()