C1000-112 Dumps - Grab Out For [NEW-2024] IBM Exam [Q50-Q67]

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C1000-112 Dumps - Grab Out For [NEW-2024] IBM Exam

C1000-112 Exam Dumps PDF Guaranteed Success with Accurate & Updated Questions

NEW QUESTION # 50
In Qasm, how are quantum gates and operations represented within a circuit?

  • A. Via quantum gates and operators like Hadamard, CNOT, etc.
  • B. Through classical logic gates
  • C. With digital symbols representing qubit states
  • D. Using classical binary instructions

Answer: A


NEW QUESTION # 51
Which code fragment will produce a maximally entangled, or Bell, state?

  • A. bell = QuantumCircuit(2)
    bell.h(0)
    bell.x(1)
    bell.cx(0, 1)
  • B. bell = QuantumCircuit(2)
    bell.h(0)
    bell.h(0)
  • C. bell = QuantumCircuit(2)
    bell.h(0)
    bell.x(1)
    bell.cz(0, 1)
  • D. bell = QuantumCircuit(2)
    bell.cx(0, 1)
    bell.h(0)
    bell.x(1)

Answer: A


NEW QUESTION # 52
Which quantum gate is used for creating superposition?

  • A. Phase gate
  • B. Hadamard gate
  • C. T gate
  • D. Pauli-Z gate

Answer: B


NEW QUESTION # 53
How are measurement results represented in quantum computing?

  • A. As a single number output
  • B. As a combination of classical and quantum bits
  • C. As a probability distribution of classical bit values
  • D. As a complex matrix of qubit states

Answer: C


NEW QUESTION # 54
What role does "benchmarking" play in quantum experiments?

  • A. Evaluating the speed of classical algorithms
  • B. Optimizing quantum gates for error-free computations
  • C. Assessing and comparing the performance of quantum hardware and simulators
  • D. Comparing the performance of quantum algorithms on different simulators

Answer: C


NEW QUESTION # 55
How does the Aer provider contribute to quantum computing experiments?

  • A. It offers error correction for noisy quantum devices
  • B. It enables visualization of quantum gates
  • C. It facilitates direct execution on quantum hardware
  • D. It provides simulators for quantum circuit simulation

Answer: D


NEW QUESTION # 56
What does the quantum operation SWAP do?

  • A. Exchanges the states of two qubits
  • B. Exchanges the phase of qubits
  • C. Implements quantum error correction
  • D. Exchanges the amplitudes of qubits

Answer: A


NEW QUESTION # 57
What is the primary function of the Aer provider in Qiskit?

  • A. Supplying high-performance quantum simulators
  • B. Providing access to quantum devices
  • C. Offering quantum algorithmic solutions
  • D. Visualizing quantum circuits

Answer: A


NEW QUESTION # 58
Which type of information is typically displayed when utilizing the show_configuration() function in Qiskit?

  • A. Quantum job configurations and setup details
  • B. Visualization of quantum gates in a circuit
  • C. User-specific configurations for quantum simulations
  • D. Displaying quantum device status and errors

Answer: A


NEW QUESTION # 59
What is the purpose of executing a quantum experiment on a simulator?

  • A. To validate quantum algorithms using classical computing resources
  • B. To measure the performance of quantum hardware
  • C. To generate random numbers efficiently
  • D. To study the behavior of classical algorithms

Answer: A


NEW QUESTION # 60
Which command is used to get the version of qiskit packages and the system information of the system?

  • A. print(__version__)
  • B. print(qiskit.__version__)
  • C. print(qiskit.__qiskit_version__)
  • D. print(qiskit_version)

Answer: C


NEW QUESTION # 61
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())

  • A. state_fidelity(), average_gate_fidelity() and process_fidelity() of 1.0
  • B. state_fidelity() and average_gate_fidelity() of 1.0
  • C. state_fidelity() of 1.0
  • D. average_gate_fidelity() and process_fidelity() of 1.0

Answer: D


NEW QUESTION # 62
Which quantum gate is similar to classical NOT gate?

  • A. Hadamard gate
  • B. CNOT gate
  • C. X gate
  • D. Y gate

Answer: C


NEW QUESTION # 63
In the below QuantumCircuit, how many Qubits are there?
bob = QuantumRegister(8,'b')
alice = ClassicalRegister(2,'a')
eve = QuantumRegister(4,'e')
qc = QuantumCircuit(bob,alice,eve)

  • A. 0
  • B. 1
  • C. 2
  • D. 3

Answer: A


NEW QUESTION # 64
How is the number of available quantum devices typically displayed in Qiskit?

  • A. As a separate downloadable file
  • B. Via a Jupyter notebook output
  • C. Using a command-line interface
  • D. Through a graphical user interface

Answer: B


NEW QUESTION # 65
Which of the following commands will result in |i> basis state?
i.e. |i> = 1/√2(|0〉+i|1〉)

  • A. H-gate followed by Z-gate
  • B. Z-gate followed by H-gate
  • C. H-gate followed by Y-gate
  • D. H-gate followed by S-gate

Answer: D


NEW QUESTION # 66
Which of the following option describes the given quantum circuit below correctly in its state_city plot?
bell = QuantumCircuit(2)
bell.h(0)
bell.x(1)
bell.cx(0,1)

  • A.
  • B.
  • C.
  • D.

Answer: C


NEW QUESTION # 67
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IBM C1000-112 certification exam is designed to test the knowledge and skills of developers in the field of quantum computation using Qiskit v0.2X. C1000-112 exam is an excellent opportunity for developers who wish to demonstrate their expertise in the field of quantum computation and showcase their ability to develop quantum applications using Qiskit v0.2X.

 

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