You're reading from Learn Quantum Computing with Python and IBM Quantum Experience A hands-on introduction to quantum computing and writing your own quantum programs with Python

Product type Paperback

Published in Sep 2020

Publisher Packt

ISBN-13 9781838981006

Length 510 pages

Edition 1st Edition

Languages

Python

Tools

IBM Quantum

Concepts

Quantum Computing

Author (1):

Robert Loredo

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Table of Contents (21) Chapters

Preface

1. Section 1: Tour of the IBM Quantum Experience (QX)

2. Chapter 1: Exploring the IBM Quantum Experience FREE CHAPTER

3. Chapter 2: Circuit Composer – Creating a Quantum Circuit

4. Chapter 3: Creating Quantum Circuits using Quantum Lab Notebooks

5. Section 2: Basics of Quantum Computing

6. Chapter 4: Understanding Basic Quantum Computing Principles

7. Chapter 5: Understanding the Quantum Bit (Qubit)

8. Chapter 6: Understanding Quantum Logic Gates

9. Section 3: Algorithms, Noise, and Other Strange Things in Quantum World

10. Chapter 7: Introducing Qiskit and its Elements

11. Chapter 8: Programming with Qiskit Terra

12. Chapter 9: Monitoring and Optimizing Quantum Circuits

13. Chapter 10: Executing Circuits Using Qiskit Aer

14. Chapter 11: Mitigating Quantum Errors Using Ignis

15. Chapter 12: Learning about Qiskit Aqua

16. Chapter 13: Understanding Quantum Algorithms

17. Chapter 14: Applying Quantum Algorithms

18. Assessments

19. Other Books You May Enjoy

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Appendix A: Resources

Summary

In this chapter, you learned about the Circuit Composer view and its many components. You created three circuits. The first one was an experiment that simulated a classic NOT gate. The second one was an experiment in which a circuit was created using the Hadamard gate, which leveraged superposition. You then viewed the results of the experiment.

The third one was a circuit in which you expanded on the second circuit in order to include your first multi-gate, that is, a CNOT gate. From here, you demonstrated entanglement.

You were also able to review your results on a histogram, which allows you to examine how both superposition and entanglement results map from your quantum circuit to the classical bit outputs, as well as how to read the probabilities based on the results.

This has provided you with the skills to experiment with other gates and see what effect each operation has on each qubit and what information might be determined or used based on the results of...