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+
+//Function to round-up a value such that it is divisible by 5
+function[v] = round_five(w)
+ v = ceil(w)
+ rem = pmodulo(v,5)
+ if (rem ~= 0)
+ v = v + (5 - rem)
+ end
+endfunction
+
+//Obtain path of solution file
+path = get_absolute_file_path('solution4_12.sce')
+//Obtain path of data file
+datapath = path + filesep() + 'data4_12.sci'
+//Clear all
+clc
+//Execute the data file
+exec(datapath)
+//Calculate the permissible tensile stress sigmat (N/mm2)
+sigmat = Sut/fs
+//Calculate the horizontal component of the force Ph (N)
+Ph = (P * 1000) * sin(theta)
+//Calculate the vertical component of the force Pv (N)
+Pv = (P * 1000) * cos(theta)
+//Calculate the maximum bending moment Mb (N-mm)
+Mb = (Ph * h) + (Pv * r)
+//Assume the value of t to be 1mm
+t = 1
+//Calculate the value of y (mm)
+y = t
+//Calculate the second moment of area I (mm4)
+I = (t * ((ratio * t)^3))/12
+//Calculate the bending stress sigmab (N/mm2)
+sigmab = (Mb * y)/I
+//Calculate the direct tensile stress D (N/mm2)
+D = Ph/(ratio * (t^2))
+//Coefficients of the resulting cubic equation
+p = [sigmat 0 (-1 * D) (-1 * sigmab)]
+//Calculate the roots to obtain the the true value of t
+r = roots(p)
+real_part = real(r)
+for i = 1:1:3
+ if(real_part(i)>0)
+ t = real_part(i)
+ break
+ end
+end
+t = round_five(t)
+//Print results
+printf('\nValue of t = %f mm\n',t)
+printf('\nArea of cross-section = (%f x %f) mm2\n',t,(ratio * t))