order of convergence of the conditional entropy (2)

Question

Let $X_n$ be a random variable distributed on $A_n:=\{1, \ldots, n\}$ and $g_n\colon A_n \to A_n$ such that $\Pr\big(X_n \neq g_n(X_n)\big) \to 0$. Putting $Y_n=g_n(X_n)$, then by Fano's inequality $$\frac{H(X_n\mid Y_n)}{\log n} \to 0,$$ which can be written $$\frac{H(X_n\mid Y_n)}{H(X_n)} \to 0 \qquad (\ast)$$ in the particular case when $X_n$ is uniformly distributed on $A_n$.

As shown by @AnthonyQuas here, $(\ast)$ fails in general. Now I'd like to know whether $$\limsup \frac{H(X_n\mid Y_n)}{H(X_n)} <1 \qquad (\ast\ast)$$ holds true in general, in the case when $H(X_n)\to \infty$.

Answer 1

I think there's a similar counterexample to the previous one. Let $X_n$ take the value 0 with probability $1-1/n$ and any value in $\{1,\ldots,N_n\}$ with probability $1/(nN_n)$. Set $Y_n=\min(X_n,1)$. Now $H(X_n|Y_n)=(1/n)\log N_n$ (the additional information in $X_n$ comes if $Y_n=1$ which has probability $1/n$; conditioned on $Y_n=1$, the expected additional information is $\log N_n$).

On the other hand, $H(X_n)=-(1-1/n)\log(1-1/n) - N(1/(nN))\log(1/(nN))\approx 1/n(\log n+\log N_n)$. Now if $N_n=2^n$, for example, then the ratio in (**) converges to 1.