QUESTION: Is Nasa currently conducting any research and development on the Joined Wing design? I flew one for the original designer, Julian Wolkovitch. ANSWER from Steve Smith on May 18, 1998: It happens that my group did a huge amount of work on Joined wings. We worked somewhat in collaboration with Wolkovitch's company. They got an SBIR phase 2 contract to build a flight demonstrator. They spent the entire value of the contract building the design capability and performing a detailed structural design for the joined wings. Their ultimate structural design capability for joined wings was really quite good, but unfortunately, there was no money left to actually build it. The aerodynamic design was done here, by me. I also did a wind tunnel test on the design. In house here at Ames, we focused on truly answering the question of whether a joined wing would make a better transport. We chose a 150 passenger, 1500 NM mission, and designed both conventional and joined wing designs. We used sophisticated structural design optimization methods and good non- planar aerodynamic models coupled to a mission simulation. The mission simulation allows you to provide the right weighting of design point and off-design performance, and insures that you satisfy all mission constraints. To give you an idea of the complexity of the simulation, the constraints were take-off and landing field length, nose-wheel unstick, static stability margin, engine out climb (2nd segment climb), Range with IFR reserves, 4 different structural loading constraints for gust and maneuver at different points in the flight envelope,fule volume, elevator control power at max dive mach number, and probably a few others I've missed. The mission variables as well as configuration variables were optimized, so cruise mach and altitude were variables, as well as thrust, span, aspect ratio, joint location, sweep, airfoil thickness, wing and tail taper, and all the aerodynamic twist variables to optimize the trimmed cruise drag, and all the structural variables to optimize the structure for minimum weight. All these were determined using a numerical optimization package called NPSOL that solves constrained optimization problems using what's called "Sequential Quadratic Programming." The optimization objective was minimum direct operating cost (DOC) for each airplane. As we went through the development of all this, we were continually adding more sophisticated analyses, and each time we did, some of the potential benefit of joined wing was lost. Finally, we included a structural constraint on rear wing (tail) buckling, and the weight increase required to prevent buckling was small, but enough to remove the last of the advantage of the joined wing...it ended up having about 3% higher DOC for the same mission, compared to a DC-9-like airplane. This isn't to say that a different mission might better exploit the joined wing to advantage. I also think there were some limitations on the designs that might have hurt the joined wing...if we did it again, we might get a slightly different answer. But not vastly different - it's going to be a small margin either way. Joined wing suffers most from short tail moment arm, so the tail down -load to trim at CL max is large, so the wing area was bigger, quite a bit bigger. I think we could help this some by tailoring the flap deflections and increasing the wing sweep, so there was less download on the tail for a given static stability margin (c.g. position). All this work generated one PHD thesis directly, and contributed to two others, as well as generating about 10 archival journal papers and nasa data reports. If you do a search for joined wings with authors John Gallman, Steve Smith, Ilan Kroo, you will find our papers. John Gallman's thesis also includes a flutter analysis of the joined wing. Since then, Boeing has done some interesting work on the joined wing as a platform for phased-array radar, with the goal of replacing the AWACS dish on top of the airplane with a radar array built onto the wings. The diamond planform gives all-aspect coverage, and as long as the performance is only adequate, they have a much more mission-capable airplane than current AWACS type airplanes. The first candidate airplane would be carrier based and replace the E-2 Hawkeye. We gave them our joined-wing structural design code, but I don't know to what extent they used it. Also going on now is some work at Lockheed on Box Wings. I extended some of our joined wing structural analysis to box wings several years ago on a consulting job. I found the box wing to be much heavier, and it also has some odd structural dynamic modes that might hurt the flutter speed. Anyway, Lockheed is hot on the idea, and I gave them the structural design code too.