vrite the python code to complete the following. Submit by copying the CODE into the answer part. If your code does not compile 1. [1] create bras and kets for the 2 qubit basis: 00, 01, 10, 11. Print out the bras and kets 2. [2] Create the quantum state |a> (1+2j)|00> + (2-j)|11>. Normalize the state. Print out both. 3. [1] From your bras and kets in question 1, create projector for the 00 state. Print this out. 4. [2] Use the projector and other bras/kets to calculate the probability of a measurement of the |a> state resulting in |00>. Print out the probability 5. [2] The Cnot gate is given by: |00><00| +|01><01| + |11><10|+|10><11|. Use your bras and kets from question 1 to create the Cnot gate. Print out the Cnot tensor. 5. [2] Use the Cnot gate on the state [a>. with regards to |a> and Cnot|a>, determine which are entangled and which are product states. Print out this statement.

please answer part 3 only 

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write the python code to complete the following. Submit by copying the CODE into the answer part. If your code does not compile |1. [1] create bras and kets for the 2 qubit basis: 00, 01, 10, 11. Print out the bras and kets 2. [2] Create the quantum state Ja> = (1+2j)|00> + (2-j)|11>. Normalize the state. Print out both. 3. [1] From your bras and kets in question 1, create projector for the 00 state. Print this out. 4. [2] Use the projector and other bras/kets to calculate the probability of a measurement of the |a> state resulting in |00>. Print out the probability 5. [2] The Cnot gate is given by: |00><00| +|01><01| + |11><10|+|10><11|. Use your bras and kets from question 1 to create the Cnot gate. Print out the Cnot tensor. 6. [2] Use the Cnot gate on the state |a>. with regards to |a> and Cnot|a>, determine which are entangled and which are product states. Print out this statement.