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Designing and Implementing Microsoft Azure Networking Solutions

You're reading from   Designing and Implementing Microsoft Azure Networking Solutions Exam Ref AZ-700 preparation guide

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Product type Paperback
Published in Aug 2023
Publisher Packt
ISBN-13 9781803242033
Length 524 pages
Edition 1st Edition
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Author (1):
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David Okeyode David Okeyode
Author Profile Icon David Okeyode
David Okeyode
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Table of Contents (17) Chapters Close

Preface 1. Part 1: Design and Implement Core Networking Infrastructure in Azure FREE CHAPTER
2. Chapter 1: Azure Networking Fundamentals 3. Chapter 2: Designing and Implementing Name Resolution 4. Chapter 3: Design, Implement, and Manage VNet Routing 5. Chapter 4: Design and Implement Cross-VNet Connectivity 6. Part 2: Design, Implement, and Manage Hybrid Networking
7. Chapter 5: Design and Implement Hybrid Network Connectivity with VPN Gateway 8. Chapter 6: Designing and Implementing Hybrid Network Connectivity with the ExpressRoute Gateway 9. Chapter 7: Design and Implement Hybrid Network Connectivity with Virtual WAN 10. Chapter 8: Designing and Implementing Network Security 11. Part 3: Design and Implement Traffic Management and Network Monitoring
12. Chapter 9: Designing and Implementing Application Delivery Services 13. Chapter 10: Designing and Implementing Platform Service Connectivity 14. Chapter 11: Monitoring Networks in Azure 15. Index 16. Other Books You May Enjoy

Understanding Azure VNet

Before we get too far into Azure networking concepts, let’s establish what Azure VNet is and the capabilities that it provides.

A VNet is a virtual version of a physical network, implemented on the Azure cloud platform. The main advantage that it has over a traditional network is that we don’t need to implement or maintain the underlying physical hardware for this network (these responsibilities are offloaded to our cloud provider – Microsoft). But for the most part, we can achieve similar capabilities and architectures that we can achieve on-premises. We can even implement more flexible architectures with Azure VNets due to the software-defined nature.

So, what capabilities does Azure VNet provide? Here is a short list of some use cases:

  • Connectivity for supported Azure services including VM, virtual machine scale sets (VMSSs), and 32 other services
  • Native Internal TCP/UDP Load Balancing and proxy systems for Internal HTTP(S) Load Balancing
  • Connects to on-premises networks using Cloud VPN tunnels and Cloud Interconnect attachments

Limitation

An Azure subscription can have up to 1,000 VNets as of the time of writing (April, 2022). An additional subscription will be needed to grow beyond this limit.

Azure VNet versus traditional networks

Even though Azure VNet is similar to a traditional on-premises network in many ways, there are still important differences, mainly due to restrictions that have been put in place by Microsoft to ensure security in a multi-tenant platform such as Azure. Here are some key ones:

  • Azure VNet does not support Layer-2 semantics (Only Layer-3 and Layer-4). This means that concepts such as virtual LANs (vLANs) and Layer-2 broadcasts don’t work in Azure VNet. Figure 1.1 shows the output of running the arp -a command on a VM that is deployed in Azure VNet. You will notice that the MAC address resolution for VMs in the same subnet results in the same 12:34:56:78:9a:bc value. This is because we are on a shared platform and the VNet is a Layer-3 overlay instead of Layer-2:
Figure 1.1 – ARP table on an Azure VM

Figure 1.1 – ARP table on an Azure VM

  • Another key difference between a traditional network and Azure VNet is that some protocols and communication types are restricted from being used in Azure VNet. Protocols such as multicast, broadcast, DHCP unicast, UDP source port 65330, IP-in-IP encapsulated packets, and Generic Routing Encapsulation (GRE) packets are not allowed in Azure VNet. Any application or service capability that requires these protocols or communication types will need to be refactored before deployment into Azure VNet for it to work. The only protocols that are allowed are TCP, UDP, ICMP, and Unicast communication (except source port UDP/68 /, destination port UDP/67, and UDP source port 65330, which is reserved for the host).

Note

For more information on the differences of Azure VNet and traditional networks, refer to the document at https://docs.microsoft.com/en-us/azure/virtual-network/virtual-networks-faq.

Now that you have some fundamental information on what Azure VNet is, let’s discuss how you would go about planning one, starting with considerations around naming it.

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