h=-1/2gt2+v0t+h0  No solutions found Reformatting the input : Changes made to your input should not affect the solution:  (1): "h0"   was replaced by   "h^0".  1 more similar replacement(s). ...

\displaystyle{g}'{\left({t}\right)}=-\frac{{{250}{t}^{{3}}+{75}{t}^{{2}}+{5}}}{{{25}{t}^{{6}}+{10}{t}^{{4}}+{t}^{{2}}}} \displaystyle{g}{''}{\left({t}\right)}=\frac{{{10}{\left({375}{t}^{{5}}+{150}{t}^{{4}}-{25}{t}^{{3}}+{15}{t}^{{2}}+{1}\right)}}}{{{t}^{{3}}{\left({5}{t}^{{2}}+{1}\right)}^{{3}}}} ...

h(t)=(-1/2)gt2+vot+ho  No solutions found Rearrange: Rearrange the equation by subtracting what is to the right of the equal sign from both sides of the equation : ...

h=\frac{1}{2}gt^2+V_0t 2h=gt^2+2V_0t gt^2+2V_0t-2h=0 now use this formula for Quadratic equation:ax^2+bx+c=0; x=\dfrac{-b\pm\sqrt{b^2-4ac}}{2a} so: t=\dfrac{-2V_0\pm\sqrt{4V_0^2+8gh}}{2g} ...

We have v=\frac{ds}{dt}=\sqrt{2gs} \implies \frac{ds}{\sqrt s}=\sqrt{2g}\, dt \implies 2\sqrt s=\sqrt{2g}\, t+c Edit to help the OP step by step: \implies 4s=2gt^2+2c\sqrt{2g}\, t+c^2 \implies s=\frac12gt^2+\frac12c\sqrt{2g}\, t+\frac14c^2 ...

We know the cosine rule, c^2 = a^2 + b^2 - 2ab\cos\theta. a^2+b^2\gt\frac{c^2}{2} implies, a^2+b^2 \gt -2ab\cos\theta transferring 2ab term into LHS. we get \frac{a^2+b^2}{2ab} \gt -\cos\theta ...