Concerning Y+: The optimization is done. I was just checking to see if the incrementally optimized configurations are better than when we optimize for all 44 antennas (16 in common with Conway) and then make the best intermediate configurations given what the full resolution Y+ then dictates. I consider 11 different Y+ configurations (each made by moving 4 antennas, or one day's worth of moving, the final being full resolution), and given the station locations defined by the full optimization, I've found the intermediate configurations which provide the best inner sidelobes -- which are up to 13% in the middle, back down to <8% for the full Y+. (I should note that Conway's configuration actually has a 5% inner sidelobe level, as defined by the snapshot dirty beam minus the best-fit Gaussian. That 5% sidelobe level is hidden in the wings of the Gaussian-like dirty beam, and the largest sidelobes which are distinct from the main lobe are much lower for Conway's arrays.) Minimizing far out sidelobes and obtaining a good main lobe beam shape also entered into the optimization as secondary factors. Far out sidelobes don't matter so much because earth rotation synthesis very quickly smears them out, while the near-in sidelobes are typically reduced by only a factor of 2 over a 4 hour integration. When we optimize the station locations 4-at-a-time (ie, incremental optimization), we actually do much worse, and the inner sidelobes exceed 30% for the full resolution Y+ array and are never better than the full-resolution-optimized intermediate Y+ configurations. Why is this so much worse? When we optimize the locations of all 44 pads, we are doing some pretty complex fringe cancellation to get the low (<8%) sidelobes, but when we only optimize 4 antennas at a time, we apparently don't have enough degrees of freedom to do what we need to get low sidelobes. The 4-at-a-time incrementally optimized arrays have main lobes which are closer to the desired circularity (10% N-S elongation, or circular for a snapshot at dec=-48 deg) than do the intermediate arrays for the single full resolution Y+ optimization. The 4-at-a-time optimization typically gives us about 6% away from the optimal beam elongation, while some of the intermediate Y+ configurations of the full-resolution optimization are off by 15% in beam elongation. As the near-in sidelobes are the biggest problem for the Y+ configuration set, optimization of the full resolution Y+ array followed by optimizing the order of antennas to move is the best way to go. The exercise permits me to say "I think this is a good configuration set", mainly because I have worked hard to find a better set, and that one turned out to be significantly worse.