static void Main(string[] args) { #region Setup // We begin by defining a quantum simulator to be our target // machine. var sim = new QuantumSimulator(throwOnReleasingQubitsNotInZeroState: true); #endregion #region Measuring One Qubit // In this region, we call the MeasurementOneQubit operation // from Measurement.qs, which prepares a qubit in the |+〉 ≔ H|0〉 // state and asserts that the probability of observing a Zero // result is 50%. // Thus, we will run the operation several times and report // the mean. var averageResult = Enumerable.Range(0, 100).Select((idx) => MeasurementOneQubit.Run(sim).Result == Simulation.Core.Result.One ? 1 : 0 ).Average(); System.Console.WriteLine($"Frequency of 〈0| given H|0〉: {averageResult}"); Pause(); #endregion #region Measuring Two Qubits // Next, we generalize to consider measuring two qubits, each // in the Z-basis. The MeasurementTwoQubits operation // returns a (Result, Result), one for each qubit; let's print // out a few such measurements. foreach (var idxMeasurment in Enumerable.Range(0, 8)) { var results = MeasurementTwoQubits.Run(sim).Result; System.Console.WriteLine($"Measured HH|00〉 and observed {results}."); } Pause(); #endregion #region Measuring in the Bell Basis // Finally, we demonstrate that if we measure each half of // the entangled pair CNOT₀₁ · H |00〉 = (|00〉 + |11〉) / sqrt(2), // the parity of the observed results is always positive. That is, // unlike in the previous example, the two Result values are // always the same. foreach (var idxMeasurment in Enumerable.Range(0, 8)) { var results = MeasurementBellBasis.Run(sim).Result; System.Console.WriteLine($"Measured CNOT₀₁ · H |00〉 and observed {results}."); } #endregion System.Console.WriteLine("\n\nPress Enter to continue...\n\n"); System.Console.ReadLine(); }
/// <summary> /// Sample to show that one can substitue the operation factory /// to run on different types of machines. /// </summary> /// <param name="args"></param> static void Main(string[] args) { var factory = new ConsoleDriver(); //Using different Factory Console.WriteLine("Hadamard to Qasm"); MeasurementOneQubit.Run(factory).Wait(); Console.WriteLine("Press Enter to continue..."); Console.ReadLine(); Console.WriteLine("Measurement bell curve to Qasm"); MeasurementBellBasis.Run(factory).Wait(); Console.WriteLine("Press Enter to continue..."); Console.ReadLine(); }
/// <summary> /// Sample to show that one can substitue the operation factory /// to run on different types of machines. /// </summary> /// <param name="args"></param> static void Main(string[] args) { //You need to replace this with your own key from the quantum experience var apiKey = "4616efdc29c9d4d751b3cd23a2e7d677ef8a..........623614734c2e11e25f9"; if (apiKey.Contains(".")) { Console.Error.WriteLine("Did you put an api key in Driver.cs ? Without that, it will not work."); return; } var factory = new IbmQx4(apiKey); //Using different Factory Console.WriteLine("Hadamard on IBMQx4"); for (int i = 0; i < 1; i++) { var result = MeasurementOneQubit.Run(factory).Result; Console.WriteLine($"Result of Hadamard is {result}"); } Console.WriteLine("Press Enter to continue..."); Console.ReadLine(); }