Q2. What is the reason for the drop in convergence rates for the gradient?
The fact that the pressure itself is converging at the optimal rate indicates that the drop in convergence rates for the gradient is caused by spatial rather than temporal error.
Q3. How is the inversion of the Laplacian in the projection made efficient?
Since the test problems studied in the next section are all set in a periodic channel, the inversion of the Laplacian in the projection is made efficient by first taking the discrete Fourier transform of the equation in the x-direction.
Q4. How many errors are estimated in the velocity and pressure?
The errors are estimated at time 0.25 in the u-component of the velocity and the pressure when the maximum value of u is about 0.86, while the maximum of v has dropped to about 0.39.
Q5. What is the class of incremental pressure projection methods discussed in this paper?
The class of incremental pressure projection methods discussed in this paper is characterized by the choice of three ingredients: the approximation to the pressure gradient term in the momentum equation, the formula used for the global pressure update during the time step, and the boundary conditions.
Q6. How can the authors approximate the solution of the coupled system?
a fractional step procedure can be used to approximate the solution of the coupled system by first solving an analog to Eq. (5) (without regard to the divergence constraint) for an intermediate quantity u∗, and then projecting this quantity onto the space of divergence-free fields to yield un+1.
Q7. What is the definition of pressure-Poisson methods?
Methods are often categorized as “pressure-Poisson” or “projection” methods based on which form of the elliptic constraint equation is being used.
Q8. What is the second-order method proposed by Perot?
The second-order method proposed by Perot uses q = 0 and replaces the pressure-update formula (12) with(I + ν1t 2 ∇2 ) pn+1/2 = φn+1. (25)This method still only obtains first-order convergence in the pressure since n̂ · ∇ p = 0 is the boundary condition used for the elliptic pressure equation.
Q9. What is the continuity of u in time?
The continuity of ∇φ in time is implied by the fact that u∗ satisfies an elliptic equation with continuous forcing and 1t∇φ is simply (I− P)u∗.
Q10. What is the difference between projection method II and the other methods?
projection method II has substantially less error in the divergence of un than the other methods, and this error appears to be converging to zero at a higher rate than the other methods.
Q11. What is the need for the extrapolation of the velocity and pressure?
In the next section it is shown that this extrapolation is necessary for the resulting velocity and pressure to be second-order accurate in the maximum norm.