Let $X_1,ldots,X_n$ be iid from a cdf $F$ on $R^d$, $X_1^*,ldots,X_n^*$ iid from empirical cdf $F_n$. Let $F_n^*$ be empirical cdf based on $X_i^*$‘s. Using DKW inequality, Let $rholeft(F_1,F_2right)=left|F_1-F_2right|$ How to show that
(a)${{rho }_{infty }}left(F_{n}^{*},Fright)xrightarrow{a.s}0$
(b)${{rho }_{infty }}left(F_{n}^{*},Fright)={{O}_{p}}left({{n}^{-frac{1}{2}}}right)$
(c)${{rho }_{L_p}}(F_{n}^{*},F)={{O}_{p}}({{n}^{-frac{1}{2}}})$
My thought is that
(a)
begin{equation}
begin{aligned}
P({{rho }_{infty }}(F_{n}^{*},F)>z)& < P({{rho }_{infty }}(F_{n}^{*},{{F}_{n}})+{{rho }_{infty}}left({{F}_{n}},Fright)>z) \
& < int_{0}^{z}{P({{rho }_{infty }}({{F}_{n}},F)>{{z}_{1}})}P({{rho }_{infty }}(F_{n}^{*},{{F}_{n}})>z-{{z}_{1}})mathrm d{{z}_{1}} quad text{(Correct?)}\
& le int_{0}^{z}{{{C}_{varepsilon ,d}}{{e}^{-(2-varepsilon )nz_{1}^{2}}}{{{{C}’}}_{varepsilon ,d}}{{e}^{-(2-varepsilon )n{{(z-{{z}_{1}})}^{2}}}}d{{z}_{1}}} (DKW)\
& ={{C}_{varepsilon ,d}}{{{{C}’}}_{varepsilon ,d}}int_{0}^{z}{{{e}^{-(2-varepsilon )nz_{1}^{2}}}{{e}^{-(2-varepsilon )n{{(z-{{z}_{1}})}^{2}}}}d{{z}_{1}}} \
& ={{C}_{varepsilon ,d}}{{{{C}’}}_{varepsilon ,d}}int_{0}^{z}{{{e}^{-(2-varepsilon )n({{z}^{2}}-2{{z}_{1}}z+2z_{1}^{2})}}d{{z}_{1}}} \
& ={{C}_{varepsilon ,d}}{{{{C}’}}_{varepsilon ,d}}{{e}^{frac{-(2-varepsilon )n{{z}^{2}}}{2}}}int_{0}^{z}{{{e}^{-(2-varepsilon )n2{{({{z}_{1}}-frac{z}{2})}^{2}}}}d{{z}_{1}}propto {{{{C}”}}_{varepsilon ,d}}{{e}^{-{{C}_{varepsilon ,d}}^{prime prime prime }n{{z}^{2}}}}}
end{aligned}
end{equation}
begin{equation}
sumlimits_{n=1}^{infty }{P({{rho }_{infty }}(F_{n}^{*},F)>z)le sumlimits_{n=1}^{infty }{{{{{C}”}}_{varepsilon ,d}}{{e}^{-{{C}_{varepsilon ,d}}^{prime prime prime }n{{z}^{2}}}}}}<infty
end{equation}
begin{equation}
{{rho }_{infty }}(F_{n}^{*},F)xrightarrow{a.s}0
end{equation}
(b)
From part a $P({{rho }_{infty }}(F_{n}^{*},F)>z)le C{{e}^{an{{z}^{2}}}}$, where $a,C$ are constant. Let $ C{{e}^{an{{z}^{2}}}}=epsilon$, then we can derive $z=sqrt{frac{ln varepsilon -ln C}{an}}$. So $exists$ constant ${{D}_{varepsilon }}=frac{sqrt{ln varepsilon -ln C}}{sqrt{a}}$ s.t. $forallepsilon>0$, $P({{rho }_{infty }}(F_{n}^{*},F)>frac{{{D}_{varepsilon }}}{sqrt{n}})le varepsilon $. In other words, ${{rho }_{infty }}(F_{n}^{*},F)={{O}_{p}}({{n}^{-frac{1}{2}}})$.
(c)$$rho_{L_p}=|F_n^*-F|_{L_p}le|F_n^*-F_n|_{L_p}+|F_n-F|_{L_p}le(|F_n^*-F_n|_{infty}|F_n^*-F_n|_{L_1})^{frac{1}{p}}+(|F_n-F|_{infty}|F_n-F|_{L_1})^{frac{1}{p}}$$
Then I think we can also use DKW inequality, but I don’t know how to deal with this $||_{L_1}$, do you have some ideas?
