From 0e05aa0f7f444f14078ad37615acc086bf7216e8 Mon Sep 17 00:00:00 2001 From: Sonia Lopez <74979440+SoniaLopezBravo@users.noreply.github.com> Date: Mon, 19 Aug 2024 20:01:16 +0200 Subject: [PATCH] Update katas/content/preparing_states/even_sup_two_qubits_complex_phases/solution.md Co-authored-by: Mariia Mykhailova --- .../even_sup_two_qubits_complex_phases/solution.md | 2 +- 1 file changed, 1 insertion(+), 1 deletion(-) diff --git a/katas/content/preparing_states/even_sup_two_qubits_complex_phases/solution.md b/katas/content/preparing_states/even_sup_two_qubits_complex_phases/solution.md index 4e3f03817d..5a9d570ac8 100644 --- a/katas/content/preparing_states/even_sup_two_qubits_complex_phases/solution.md +++ b/katas/content/preparing_states/even_sup_two_qubits_complex_phases/solution.md @@ -11,7 +11,7 @@ $$ The fact that you were able to factor out the state into a tensor product of two terms means the state is separable. -This is looking promising. Now let’s try to approach the problem from the other end, that is from the starting state of $\ket{00}$. +This is looking promising. Now let’s try to approach the problem from the other end, that is, from the starting state of $\ket{00}$. As you've seen in the previous task, applying a Hadamard operation to each $\ket{0}$ gets you closer to the factored-out expression: $$