Answer to Question #203192 in Real Analysis for Rajkumar

When P is the position that divides [1,5] into four equal parts. The position of [1,5] into these parts are, "P=[I_1, I_2, I_3, I_4]"

Where I₁=[1,2], I₂=[2,3],I₃=[3,4],I₄=[4,5]

Now the length of each interval is given by

"S_1=2-1=1= \\triangle x_1"

"S_2=3-2=1= \\triangle x_2"

"S_3=4-3=1= \\triangle x_3"

"S_4=5-4=1= \\triangle x_4"

Now the downbound of the function f(x) corresponding to each interval is given by

"\\therefore f(x)=x^2-2"

"m_1=1^2-2=-1"

"m_2=2^2-2=2"

"m_3=3^2-2=7"

"m_4=4^2-2=14"

"L(p,f)= \\sum_{r=1}^4 m_r \\triangle x_r =m_1 \\triangle x_1+m_2 \\triangle x_2+m_3 \\triangle x_3+m_4\\triangle x_4"

"L(p,f) =-1*1+2*1+7*1+14*1 =-1+2+7+14=22"

Now "-P=[-I_1, -I_2, -I_3, -I_4]"

Where I'₁=[-1,-2], I'₂=[-2,-3],I'₃=[-3,-4],I'₄=[-4,-5]

The length of each interval = "1 = \\triangle x_r \\space \\space \\space 1 \\eqslantless r \\eqslantless 4"

The upperbound of "f(x)=x^2-2" over each interval is given by

"\\therefore f(x)=x^2-2"

"m_1=(-1)^2-2=-1"

"m_2=(-2)^2-2=2"

"m_3=(-3)^2-2=7"

"m_4=(-4)^2-2=14"

The upper sum is defined as

"U(-p,f)= \\sum_{r=1}^4 m_r \\triangle x_r"

"U(-p,f) =-1*1+2*1+7*1+14*1 =-1+2+7+14=22"

Hence "L(p,f)=U(-p,f)" verified

We also know that the upper sum is always greater than the lower sum, hence

"L(p,f)\\eqslantless U(-p,f)" verified