You're reading from Quantum Computing in Practice with Qiskit® and IBM Quantum Experience® Practical recipes for quantum computer coding at the gate and algorithm level with Python

Product type Paperback

Published in Nov 2020

Publisher Packt

ISBN-13 9781838828448

Length 408 pages

Edition 1st Edition

Languages

Python

Tools

IBM Quantum

Concepts

Quantum Computing

Author (1):

Hassi Norlen

View More author details

Table of Contents (12) Chapters

Preface

1. Chapter 1: Preparing Your Environment

2. Chapter 2: Quantum Computing and Qubits with Python FREE CHAPTER

3. Chapter 3: IBM Quantum Experience® – Quantum Drag and Drop

4. Chapter 4: Starting at the Ground Level with Terra

5. Chapter 5: Touring the IBM Quantum® Hardware with Qiskit®

6. Chapter 6: Understanding the Qiskit® Gate Library

7. Chapter 7: Simulating Quantum Computers with Aer

8. Chapter 8: Cleaning Up Your Quantum Act with Ignis

9. Chapter 9: Grover's Search Algorithm

10. Chapter 10: Getting to Know Algorithms with Aqua

11. Other Books You May Enjoy

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Correcting for the expected with readout correction

Now that we have some knowledge about what might go wrong when we use our qubits for quantum calculations, is there anything that we can do about it? There are essentially two approaches here, at least for the small quantum backends that we have at our disposal.

First, we can make sure that the quantum programs that we run have a fighting chance of completing before the qubits get lost due to decoherence, the T1 and T2 times that we explored. This means that we make the programs short.

Second, we can take a good look at various readout errors and see if we can mitigate those. If you remember in Chapter 7, Simulating Quantum Computers with Aer, we could pull in actual backend qubit data to qasm_simulator and have it behave like an NISQ backend. We can do the same in reverse, analyze the measurement errors for a backend, and use that data to create a mitigation map to counteract erroneous measurements.