Model tp020r ! Source version 1 ! Simple APM canonicalizer version 1.3 ! APM backend version 1.1 Parameters lbx1hs = -1/2 lbx1r = 0 lbx1 = lbx1r End Parameters Variables x_1 = -2, >= lbx1, <= 1/2 x_2 = 1 obj End Variables Intermediates myminfun = 100*(x_2 - x_1^2)^2 + (1 - x_1)^2 myabsdevnod0_0 = abs(myminfun - 38.19872981077807) myreldevnod0_0 = abs(myminfun/38.19872981077807 - 1) myabsdevnod0_1 = abs(x_1 - 0.5) myreldevnod0_1 = abs(x_1/0.5 - 1) myabsdevnod0_2 = abs(x_2 - 0.8660254037844386) myreldevnod0_2 = abs(x_2/0.8660254037844386 - 1) myabsdevnod1_0 = (1/2)*(abs(myabsdevnod0_0 - myabsdevnod0_1) + (myabsdevnod0_0 + myabsdevnod0_1)) myreldevnod1_0 = (1/2)*(abs(myreldevnod0_0 - myreldevnod0_1) + (myreldevnod0_0 + myreldevnod0_1)) myabsdevnod1_2 = myabsdevnod0_2 myreldevnod1_2 = myreldevnod0_2 myabsdevnod2_0 = (1/2)*(abs(myabsdevnod1_0 - myabsdevnod1_2) + (myabsdevnod1_0 + myabsdevnod1_2)) myreldevnod2_0 = (1/2)*(abs(myreldevnod1_0 - myreldevnod1_2) + (myreldevnod1_0 + myreldevnod1_2)) zmyabsdevmax = myabsdevnod2_0 zmyreldevmax = myreldevnod2_0 End Intermediates Equations obj = myminfun x_1 + x_2^2 >= 0 x_1^2 + x_2 >= 0 x_1^2 + x_2^2 - 1 >= 0 End Equations End Model