An article from describes the importance of having a robust network architecture, and the benefits of a scalable network architecture.

A network is comprised of multiple physical devices, each of which connects to the rest of the network through a dedicated physical link.

When you add in multiple physical links, the network can also support many more devices on the network, such as multiple video cameras, multiple data centers, multiple servers, and so on. 

The internet of things can help solve these problems, because it can scale with the number of devices.

For example, imagine you have 10,000 devices connected to the internet.

This network has 10 million links, and each link has a minimum number of 10.

You could have 10 links with a minimum of 10 physical links each, but each of those 10 links is connected to 10 physical devices.

In other words, the number 10 could be increased to 20,000 if you add additional physical links. 

This network architecture is called the distributed-memory network (DNM). 

It is the best way to make the internet of devices scalable, because you can increase the number and quality of physical links in a distributed network, without adding more physical devices to the network. 

To learn more about the DNM, check out this article.

Network architectures are the best ways to scale a network.

Why network architectures matter in the internet of things era There are two main reasons for network architectures in the internet-of-things era: Network availability and throughput.

Network availability is a measure of how well the network is available for each device on the internet at any given time.

This metric can be improved through the use of networking protocols such as the Internet of Things (IoT), Bluetooth, or ZigBee.

Network availability is also measured by the number of physical devices on the network at any one time.

Since physical devices can be added to the network, there is also a connection between the device and the rest of the network (the network has multiple physical link connections).

The amount of physical link connectivity is called the network availability factor.

This number is important because the more physical link connections, the better the network will operate. 

Tiny routers that can only handle 10 devices can handle 10 million devices on a network if all of the devices are connected.

The more physical links that the network can handle, the more devices can be connected, increasing the overall network throughput.

As more devices connect to the internet, the networks performance increases.

In this way, network availability increase is a good metric to measure the performance of a network and how it can support multiple devices.

Network performance is the most important metric for a network to support many devices on it.

The more physical links the better the speed of a network.

This means that the more connectivity the less each device has to get to other physical devices. 

Networks that support multiple physical links on the same network will have higher network performance, because multiple devices can connect at the same time. 

Network throughput is also a good metric for the systems performance. 

As more devices connect at once, the higher the frequencies of these devices, the faster the system can operating because it can send information to multiple servers at once. 

If the capacity of each device on the connected network is higher than the minimum capacity of a physical link, then the physical link can provide the full capacity needed to provide information to multiple machines on the connected network. 

A good network performance can improve the performance of the total network because every physical device that is connected to another device has a minimum capacity.

 It is also important to understand the different types of network devices that are used in the IoT era. 

There are devices such as routers and switches that can provide multiple connections to many physical devices on the same internet network at the same  time. 

These devices can be used in the same network to deliver information and services to multiple physical nodes. 

Additionally, wireless devices such as bluetooth and ZigBee can also provider multiple connection to the same network as a wireless device. 

 It can also be possible to use the wireless devices to provides multiple