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Ace the C1000-112 Fundamentals of Quantum Computation Using Qiskit v0.2X Developer 2023 exam with our comprehensive trai

Are you interested in becoming a certified Quantum Computation Developer? The C1000-112 Fundamentals of Quantum Computation Using Qiskit v0.2X Developer 2023 exam is your ticket to the world of quantum computing. But first, you need to prepare for the exam and make sure you have the necessary skills and knowledge to pass it. Quantum computing is a rapidly growing field with immense potential to transform various industries, such as healthcare, finance, and cybersecurity. Itu2019s also an area with a significant shortage of skilled professionals.<br>https://www.certschief.com/C1000-112/

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Ace the C1000-112 Fundamentals of Quantum Computation Using Qiskit v0.2X Developer 2023 exam with our comprehensive trai

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  1. CertsChief Guaranteed Success with Accurate & Updated Questions. IBM C1000-112 Fundamentals of Quantum Computation Using Qiskit v0.2X Developer Questions & Answers PDF For More Information - Visit: https://www.certschief.com/ ProductFull Version Features:  90 Days Free Updates  30 Days Money Back Guarantee  Instant Download Once Purchased  24/7 Online Chat Support Visit us athttps://www.certschief.com/c1000-112/

  2. Latest Version: 6.0 Question: 1 S-gate is a Qiskit phase gate with what value of the phase parameter? Response: A.π/8 B.π/4 C.π D.π/2 Answer: D Question: 2 Which two options would place a barrier across all qubits to the QuantumCircuit below? qc = QuantumCircuit(3,3) Response: A.qc.barrier(qc) B.qc.barrier([0,1,2]) C.qc.barrier() D.qc.barrier(3) E.qc.barrier_all() Answer: B,C Question: 3 Which code fragment would yield an operator that represents a single-qubit X gate? Response: A.op = Operator.Xop(0) B.qc = QuantumCircuit(1) C.qc.x(0) D.op = Operator(qc) E.op = Operator([[0,1]]) F.op = Operator([[1,0,0,1]]) Answer: B Visit us athttps://www.certschief.com/c1000-112/

  3. Question: 4 What would be the fidelity result(s) for these two operators, which differ only by global phase? op_a = Operator(XGate()) op_b = numpy.exp(1j * 0.5) * Operator(XGate()) Response: A.state_fidelity() of 1.0 B.state_fidelity() and average_gate_fidelity() of 1.0 C.average_gate_fidelity() and process_fidelity() of 1.0 D.state_fidelity(), average_gate_fidelity() and process_fidelity() of 1.0 Answer: C Question: 5 Which three simulators are available in BasicAer? Response: A.qasm_simulator B.basic_qasm_simulator C.statevector_simulator D.unitary_simulator E.quantum_simulator F.quantum_circuit_simulator Answer: A,C,D Question: 6 Which code fragment will produce a maximally entangled, or Bell, state? Response: A.bell = QuantumCircuit(2) bell.h(0) bell.x(1) bell.cx(0, 1) B.bell = QuantumCircuit(2) bell.cx(0, 1) bell.h(0) bell.x(1) Visit us athttps://www.certschief.com/c1000-112/

  4. C.bell = QuantumCircuit(2) bell.h(0) bell.x(1) bell.cz(0, 1) D.bell = QuantumCircuit(2) bell.h(0) bell.h(0) Answer: A Question: 7 Which line of code would assign a statevector simulator object to the variable backend? Response: A.backend = BasicAer.StatevectorSimulatorPy() B.backend = BasicAer.get_backend('statevector_simulator') C.backend = BasicAer.StatevectorSimulatorPy().name() D.backend = BasicAer.get_back('statevector_simulator') Answer: B Question: 8 Which statement will create a quantum circuit with four quantum bits and four classical bits? Response: A.QuantumCircuit(4, 4) B.QuantumCircuit(4) C.QuantumCircuit(QuantumRegister(4, 'qr0'), QuantumRegister(4, 'cr1')) D.QuantumCircuit([4, 4]) Answer: A Question: 9 Which code fragment will produce a multi-qubit gate other than a CNOT? Response: A.qc.cx(0,1) B.qc.cnot(0,1) C.qc.mct([0],1) Visit us athttps://www.certschief.com/c1000-112/

  5. D.qc.cz(0,1) Answer: D Visit us athttps://www.certschief.com/c1000-112/

  6. For More Information - Visit: http://www.certschief.com/ Disc ount Coupon Code: Page | 1 http://www.certschief.com/exam/0B0-104/ CERT S CHIEF10 Visit us athttps://www.certschief.com/c1000-112/ Powered by TCPDF (www.tcpdf.org)

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