Probabilistic Cloning: Difference between revisions

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'''The quantum circuit'''
'''The quantum circuit'''
  \hrule
Finally, the quantum circuit which illustrates the above stages consists of following gates and parts which have been also shown in the figure in [[Probabilistic Cloning#Outline|Outline]]
Finally, the quantum circuit which illustrates the above stages consists of following gates and parts which have been also shown in the figure in [[Probabilistic Cloning#Outline|Outline]]
* Reverse Controlled $U_1$ gate: A controlled unitary gates with the <math>x</math> (original) qubit as the control qubit and the <math>z</math> qubit as the operational qubit. The unitary gate <math>U_1</math> acts only if the control qubit is <math>|0\rangle</math>. The unitary <math>U_1</math> is:</br>
* Reverse Controlled $U_1$ gate: A controlled unitary gates with the <math>x</math> (original) qubit as the control qubit and the <math>z</math> qubit as the operational qubit. The unitary gate <math>U_1</math> acts only if the control qubit is <math>|0\rangle</math>. The unitary <math>U_1</math> is:</br>
    <math>U_1 = sin\beta |0\rangle\langle 0| + cos\beta |1\rangle\langle 0| + cos\beta |1\rangle\langle 0| - sin\beta |1\rangle\langle 1|</math></br>
<math>U_1 = sin\beta |0\rangle\langle 0| + cos\beta |1\rangle\langle 0| + cos\beta |1\rangle\langle 0| - sin\beta |1\rangle\langle 1|</math></br>
where the <math>\beta = arcsin(\sqrt{\frac{1+tan^4\eta}{2}})</math>
where the <math>\beta = arcsin(\sqrt{\frac{1+tan^4\eta}{2}})</math>
* A normal [[CNOT]] gate: The control qubit is <math>y</math> and the operational qubit is <math>x</math> (The flip occurs if the control qubit is <math>|1\rangle</math>)
* A normal [[CNOT]] gate: The control qubit is <math>y</math> and the operational qubit is <math>x</math> (The flip occurs if the control qubit is <math>|1\rangle</math>)
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<math>U_2 = sin\delta |0\rangle\langle 0| + cos\delta |1\rangle\langle 0| + cos\delta |1\rangle\langle 0| - sin\delta |1\rangle\langle 1|</math></br>
<math>U_2 = sin\delta |0\rangle\langle 0| + cos\delta |1\rangle\langle 0| + cos\delta |1\rangle\langle 0| - sin\delta |1\rangle\langle 1|</math></br>
where the <math>\delta = arcsin[(\sqrt{\frac{2}{1+tan^4\eta}} + \sqrt{\frac{2}{1+tan^{-4}\eta}})/2]</math>
where the <math>\delta = arcsin[(\sqrt{\frac{2}{1+tan^4\eta}} + \sqrt{\frac{2}{1+tan^{-4}\eta}})/2]</math>
* [[Hadamard gate: A Hadamard gate on qubit $y$
* [[Hadamard gate]]: A Hadamard gate on qubit <math>y</math>
* Measurement part: Measuring qubit <math>z</math> in the standard basis.
* Measurement part: Measuring qubit <math>z</math> in the standard basis.


==Further Information==
==Further Information==
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