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A language <math>L</math> is recursively enumerable, iff there is a Turing Machine <math>M</math>, which can enumerate all the strings of <math>L</math>. | A language <math>L</math> is recursively enumerable, iff there is a Turing Machine <math>M</math>, which can enumerate all the strings of <math>L</math>. | ||
− | So, suppose <math>L_2</math> is decidable. Now we have a <math>TM</math> <math>T</math>, which can enumerate all strings of <math>L_2</math>. For each of these strings <math>w</math>, we can find <math>x</math>, such that <math>f(x) = w</math>, using the function $f^{-1}$. Since $f^{-1}$ is bijective, it ensures that for each of the string <math>w</math> enumerated by <math>T</math>, we are getting a unique $f^{-1}(w)$ (because of one-one property of bijection) and we are guaranteed that we'll generate all strings of $L_1$ (because of "co-domain = range" property of bijection),. i.e.; we are actually enumerating all strings of <math>L_1</math>. Thus, <math>L_1</math> should also be recursively enumerable. | + | So, suppose <math>L_2</math> is decidable. Now we have a <math>TM</math> <math>T</math>, which can enumerate all strings of <math>L_2</math>. For each of these strings <math>w</math>, we can find <math>x</math>, such that <math>f(x) = w</math>, using the function $f^{-1}$. Since $f^{-1}$ is bijective, it ensures that for each of the string <math>w</math> enumerated by <math>T</math>, we are getting a unique $f^{-1}(w)$ (because of one-one property of bijection) and we are guaranteed that we'll generate all strings of $L_1$ (because of "co-domain = range" property of bijection),. i.e.; we are actually enumerating all strings of <math>L_1</math>. Thus, we are getting a <math>TM</math> which is enumerating all strings of <math>L_1</math>, which means <math>L_1</math> should also be recursively enumerable. |
Consider two languages $L_1$ and $L_2$ each on the alphabet $\Sigma$. Let $f : \Sigma → \Sigma$ be a polynomial time computable bijection such that $(\forall x) [x\in L_1$ iff $f(x) \in L_2]$. Further, let $f^{-1}$ be also polynomial time computable.
Which of the following CANNOT be true ?
(A) <math>L_1</math> Image not present P and <math>L_2</math> is finite
(B) <math>L_1</math> Image not present NP and <math>L_2</math> Image not present P
(C) <math>L_1</math> is undecidable and <math>L_2</math> is decidable
(D) <math>L_1</math> is recursively enumerable and <math>L_2</math> is recursive
A language <math>L</math> is recursively enumerable, iff there is a Turing Machine <math>M</math>, which can enumerate all the strings of <math>L</math>.
So, suppose <math>L_2</math> is decidable. Now we have a <math>TM</math> <math>T</math>, which can enumerate all strings of <math>L_2</math>. For each of these strings <math>w</math>, we can find <math>x</math>, such that <math>f(x) = w</math>, using the function $f^{-1}$. Since $f^{-1}$ is bijective, it ensures that for each of the string <math>w</math> enumerated by <math>T</math>, we are getting a unique $f^{-1}(w)$ (because of one-one property of bijection) and we are guaranteed that we'll generate all strings of $L_1$ (because of "co-domain = range" property of bijection),. i.e.; we are actually enumerating all strings of <math>L_1</math>. Thus, we are getting a <math>TM</math> which is enumerating all strings of <math>L_1</math>, which means <math>L_1</math> should also be recursively enumerable.
Consider two languages $L_1$ and $L_2$ each on the alphabet $\Sigma$. Let $f : \Sigma → \Sigma$ be a polynomial time computable bijection such that $(\forall x) [x\in L_1$ iff $f(x) \in L_2]$. Further, let $f^{-1}$ be also polynomial time computable.
Which of the following CANNOT be true ?
(A) <math>L_1</math> Image not present P and <math>L_2</math> is finite
(B) <math>L_1</math> Image not present NP and <math>L_2</math> Image not present P
(C) <math>L_1</math> is undecidable and <math>L_2</math> is decidable
(D) <math>L_1</math> is recursively enumerable and <math>L_2</math> is recursive
A language <math>L</math> is recursively enumerable, iff there is a Turing Machine <math>M</math>, which can enumerate all the strings of <math>L</math>.
So, suppose <math>L_2</math> is decidable. Now we have a <math>TM</math> <math>T</math>, which can enumerate all strings of <math>L_2</math>. For each of these strings <math>w</math>, we can find <math>x</math>, such that <math>f(x) = w</math>, using the function $f^{-1}$. Since $f^{-1}$ is bijective, it ensures that for each of the string <math>w</math> enumerated by <math>T</math>, we are getting a unique $f^{-1}(w)$ (because of one-one property of bijection) and we are guaranteed that we'll generate all strings of $L_1$ (because of "co-domain = range" property of bijection),. i.e.; we are actually enumerating all strings of <math>L_1</math>. Thus, we are getting a <math>TM</math> which is enumerating all strings of <math>L_1</math>, which means <math>L_1</math> should also be recursively enumerable.