Bluetooth® technology is one of the world’s best known brands and one of the most ubiquitous wireless communications technologies on the planet. It’s been in existence since 2000 and has found its way into billions and billions of devices. Last year alone, over three billion Bluetooth devices were shipped by manufacturers.

Bluetooth has not stood still. Since its first incarnation, Bluetooth has been carefully and systematically improved so that it has continued to keep pace with market requirement, and continued to support and inspire innovation.

Bluetooth mesh networking is the latest chapter in this incredible technology story and 150 companies, all members of the Bluetooth SIG, have helped create it.

This is the first in a series of articles where we’ll introduce you to Bluetooth mesh networking. We start with a two-part overview and will then proceed to explore aspects of the technology in greater detail in subsequent parts of the series.

Flavors and Features

People interested in Bluetooth® technology will be accustomed to seeing new releases adopted by the Bluetooth SIG at regular intervals.

Typically, new releases equip Bluetooth with additional features or they improve upon existing capabilities in some way. Every now and again though, an entirely new “flavor” of Bluetooth is released; a quite distinct variant of Bluetooth, which uses radio in a different way and is optimized in its design and implementation for broad sets of use cases.

Bluetooth Basic Rate/Enhanced Data Rate (BR/EDR)  was the first flavor of Bluetooth to be released. It was intended to act as a cable replacement technology and soon came to dominate wireless audio products and be the enabler for new computer peripherals, such as wireless mice and keyboards.

Bluetooth Low Energy (LE) was the next truly distinct Bluetooth technology to appear. It was optimized to use as little energy as possible with devices that incorporate it and able to operate and communicate wirelessly, powered by only a coin-sized battery, which could often last for many years. It’s been very widely adopted. It’s hard to find a smartphone or tablet that doesn’t support Bluetooth  LE. Health, sports and fitness devices, like activity trackers, rely on Bluetooth  LE technology. So do wearables, like smart watches. The impact of this Bluetooth flavor has been impressive and widespread.

So is Bluetooth mesh networking a new flavor of Bluetooth? Or is it a new feature?

In fact, it’s neither. Let’s find out more about this exciting new Bluetooth technology, how it relates to other forms of Bluetooth, what it can do and how it works.

The Crucial Three

It’s common to find Bluetooth BR/EDR and Bluetooth  LE both available in devices like smartphones, but they do not rely on each other’s services and capabilities. To all intents and purposes, those two Bluetooth flavors work independently of each other. In fact, whilst they’re quite happy to coexist in the same device, it’s not possible to use Bluetooth BR/EDR to communicate with a Bluetooth LE device or vice versa. They’re happy in each other’s company, but they don’t talk.

In contrast, Bluetooth mesh networking uses and is dependent upon Bluetooth  LE. Bluetooth  LE is the wireless communications protocol stack which Bluetooth mesh makes use of.

Bluetooth mesh is not a wireless communications technology. It’s a networking technology.

Figure 1 shows the relationship between Bluetooth BR/EDR, Bluetooth LE and Bluetooth mesh.

Figure 1 – The relationship between Bluetooth mesh and Bluetooth LE

A Tale of Topologies

At its most basic level, Bluetooth BR/EDR lets one device connect to and communicate with another device, establishing a 1:1 relationship which is reflected in the term “pairing”, which most people will be familiar with. Some devices can have multiple 1:1 relationships with other devices and can form a kind of hub / spoke topology known as a “piconet“.

Bluetooth BR/EDR and one-to-one topologies

Bluetooth® LE devices can also form 1:1 and hub/spoke relationships with other devices, as well as work in a connectionless way, broadcasting data which any other device in direct radio range can receive. This is a 1:m topology where m can be a very large number! If devices listening to broadcasts are doing no transmitting of data themselves, then the broadcasting device has the radio spectrum to itself and there’s no effective limit to the number of other devices that can receive and make use of its broadcasts. Bluetooth beacons are an excellent example of this capability in action.

Bluetooth LE and broadcasting

Bluetooth® mesh allows us to establish a many-to-many (m:m) relationship between wireless devices. Furthermore, devices may relay data to other devices not in direct radio range of the originating device. In this way, mesh networks can span very large physical areas and contain large numbers of devices.

Bluetooth mesh networking and a many-to-many topology

Motivation for Mesh Networking

Bluetooth® mesh networking was created because mesh topologies offer the best way to meet various, increasingly common communications requirements, typified by applications such as building automation and sensor networks. Those requirements include:

  • Coverage of very large areas
  • “Just works interoperability”
  • The ability to monitor and control large numbers of devices
  • Optimized, low energy consumption
  • Efficient use of radio resources, leading to scalability
  • Compatibility with currently available smartphone, tablet and personal computer products
  • Industry-standard, government-grade security

There are other low-power wireless communications technologies which support mesh topologies, but our members often report that these technologies have unacceptable constraints and limitations, and that they are not optimal for the kinds of problems that they are trying to address and the types of products they want to create. Issues in other, comparable technologies, include low data transmission rates, limited numbers of “hops” when relaying data across the mesh, scalability limits often caused by the way radio channels are used and difficulties and delays when following procedures to change the device composition of the mesh network.

Other mesh technologies are, generally speaking, not supported by standard smartphone, tablet and PC equipment; a major constraint.

Creating an industry-standard mesh communications technology based on Bluetooth  LE, gave the opportunity to meet the requirements, but without the associated limitations and constraints. Interoperability and energy efficiency are the hallmarks of Bluetooth LE after all.

Message-Oriented Communication

Bluetooth® mesh networking uses a publish / subscribe messaging system.

Devices may send messages to addresses whose names and meaning correspond to high level concepts which users can understand, like Garden Lights. This is called publishing.

Devices can be configured to receive messages which were sent to particular addresses by other devices. This is called subscribing.

When a device publishes a message to a particular address, all the other devices that subscribed to that address will receive a copy of it, process it and react in some way.

Imagine a set of outdoor lights installed in the garden. Each light has been configured so that it subscribes to “Garden Lights” messages. Now, imagine a Bluetooth mesh light switch sending an “ON” message to the “Garden Lights” address. All of the lights in the garden will receive the “ON” message and react to it by…. you guessed it….. switching on.

It’s that simple.

Messages and Device State

State is a key concept in Bluetooth® mesh networking. Devices in a Bluetooth mesh network each have a set of independent state values, representing some condition of the device. In our garden lights example, each light has a state value which represents whether the device is currently switched on or switched off. Changing it, by publishing a message of a type whose definition means that it acts upon on/off state values, is how a Bluetooth mesh light switch is able to control lights. Changing a state value modifies a physical condition of the device itself, like switching it on or off.

Messages, states and how devices behave with respect to these and other concepts are defined in specifications known as models. Models are implemented by Bluetooth mesh devices.

We’ll talk more about devices, states, messages, state changes and models in a more formal way, in another article later in this series.

Next!

Part 2 of this article will take us deeper into the world of Bluetooth mesh networking with an overview of the way messages find their way across large mesh networks, in-market device support, security and the mesh stack itself. I’ll also describe some interesting performance optimisations in the design of Bluetooth mesh networking which make it highly efficient and an excellent fit for the mesh networking requirements of the age of the Internet of Things (IoT).

FEATURED DOWNLOAD

Bluetooth Mesh Networking: Paving the Way for Smart Lighting

Bluetooth mesh networking brings the multi-vendor interoperability, low power, and low latency pedigree of Bluetooth Low Energy to the world of commercial lighting. Discover how this innovative technology can turn wireless connectivity into a smart lighting wireless platform.

INSTANT DOWNLOAD

2021 Bluetooth Market Update

Supported by updated forecasts from ABI Research and insights from several other analyst firms, the Bluetooth Market Update highlights the latest Bluetooth trends and forecasts.

Qualified Bluetooth Mesh - Unlocking the Value of the Building

Facilities managers are growing increasingly conscious that the buildings they manage need to be…

The Largest Bluetooth Mesh Lighting Control Installation in the World!

The project itself consisted of 3,685 Bluetooth mesh McWong TruBlu lighting controllers (installed in…

Bluetooth® Talks: Bluetooth Technology for Lighting

In this webinar UL and the Bluetooth Special Interest Group (SIG) explore: Market trends…

HubSense Effortlessly Turns An Existing Installation Into An Intelligent New Light Management System

When the antiquated lighting system in an office building in Kolding, Denmark, was no…

Intelligent Light solutions for the Albrecht Dürer Exhibition

Today, we are living in a world where smart is the new normal, and…

Bluetooth Mesh for Building Automation Demo

Discover how you can extend Bluetooth connectivity with TI Bluetooth Mesh in this demo. …

Three Perspectives on Bluetooth® Mesh in Commercial Buildings

This session features a product vendor, a system vendor, and a system integrator who…

5 Must-Read Bluetooth Member Case Studies

Every year, the Bluetooth® community makes major strides that drive wireless innovation, overcome challenges,…

Bluetooth Mesh: A Healthier Wireless Option

At some point in the near future, nearly every object in the home or…

Understanding Reliability in Bluetooth® Technology

Download this detailed discussion of the issues and factors that impact the reliability of…

Bluetooth Mesh Networking Highlights and Features

This white paper provides an overview of the Bluetooth Mesh Profile and highlights some…

Energy and Cost Savings at Pioneer Markets in Mariposa and Waterford, California

Pioneer market is a family owned grocery business operating in Mariposa, California and Waterford,…

Building a Sensor-Driven Lighting Control System Based on Bluetooth® Mesh

A technical examination of which Bluetooth mesh models to use in different types of…

What is Bluetooth Mesh? | Tech Chats - with Cypress Semiconductor

Chris Anderson chats with Michael Shen of Cypress Semiconductor about Bluetooth mesh, covering a…

Multi-vendor Bluetooth Mesh SSL projects benefit warehouse and factory settings

Yamaha warehouse and Crystal bottled water facility leverage Bluetooth Mesh to slash energy use…

Bluetooth mesh models: The building blocks for interoperable products

Bluetooth® technology is a wireless standard with agreed, formal specifications that support global interoperability…

How to Deploy BlueZ on a Raspberry Pi Board as a Bluetooth Mesh Provisioner

This step-by-step study guide will teach you: How to rebuild the kernel on a…

2020 Bluetooth Market Update

Supported by updated forecasts from ABI Research and insights from several other analyst firms, the Bluetooth Market Update highlights the latest Bluetooth trends and forecasts.

How to Make Wearables Bluetooth Mesh Provisioners

Learn how to create applications for smartwatches and other platforms that can monitor and control nodes in a Bluetooth mesh network.

2019 Bluetooth Market Update

Supported by updated forecasts from ABI Research and insights from several other analyst firms, the Bluetooth Market Update highlights the latest Bluetooth trends and forecasts.

Lighting as a Platform

See how connected lighting systems are being used as a platform to enable advanced building services like wayfinding, asset tracking, and space utilization to improve the ROI of smart building investments.

An Introduction to the Bluetooth Mesh Proxy Function

Learn how to create applications for smartphones and other platforms which can monitor and control nodes in a Bluetooth mesh network.

Build a Smarter Building with Blue

See how Bluetooth increases reliability, reduces costs, and enhances your smart building ROI.

Overview – Bluetooth Mesh Networking

A quick overview outlining how Bluetooth mesh uniquely meets the reliability, scalability, and security requirements of commerical and industrial markets.