Answer:
(a) The horizontal ground reaction force [tex]F_{g,x}=325\, N[/tex]
(b) The vertical ground reaction force [tex]F_{g,y}=696\, N[/tex]
(c) The resultant ground reaction force [tex]F_g=768\, N[/tex]
Explanation:
Given
John mass , m = 65 kg
Horizontal acceleration , [tex]a_x= 5.0 \frac{m}{s^{2}}[/tex]
Vertical acceleration , [tex]a_y=0.9 \frac{m}{s^{2}}[/tex]
(a) Using Newton's 2nd law in horizontal direction
[tex]F_{g,x}=ma_x[/tex]
=>[tex]F_{g,x}=65\times 5\, N=325\, N[/tex]
Thus the horizontal ground reaction force [tex]F_{g,x}=325\, N[/tex]
(b) Using Newton's 2nd law in vertical direction
[tex]F_{g,y}-mg=ma_y[/tex]
=>[tex]F_{g,y}=mg+ma_y[/tex]
=>[tex]F_{g,y}=65\times (9.81+0.9)\, N=696\, N[/tex]
Thus the vertical ground reaction force [tex]F_{g,y}=696\, N[/tex]
(c) Resultant ground reaction force is
[tex]F_g=(F_{g,x}^{2}+F_{g,y}^{2})^{\frac{1}{2}}[/tex]
=>[tex]F_g=(325^{2}+696^{2})^{\frac{1}{2}}\, N=768\, N[/tex]
=>[tex]F_g=768\, N[/tex]
Thus the resultant ground reaction force [tex]F_g=768\, N[/tex]
