Networking Technology Steels Itself for Emerging Markets



The Bluetooth Special Interest Group (SIG) announced Bluetooth mesh technology in July. It targets industrial automation and smart buildings by extending the reach of a network, while maintaining the low energy consumption of Bluetooth technology.

The distinctive feature of Bluetooth mesh networking is that it enables many-to-many (m:m) device communication. Rather than a star topology, where one central device communicates with others in a point-to-point network (or piconet), the mesh topology allows a device to communicate with every other device in the mesh.

Bluetooth mesh networking is designed for building automation applications, such as lighting, heating, cooling, and security. It can be used to expand sensor networks, beacons and for asset tracking—locating and tracking goods in real-time across an area.

The Bluetooth mesh system is based on the Bluetooth Low Energy stack. Bluetooth Low Energy is the Wireless Personal Area Network (WPAN) technology used by smartphones, tablets, and computers in smart homes, healthcare, and entertainment.

On top of the Bluetooth Low Energy stack is a bearer layer that defines how mesh Protocol Data Units (PDUs) will be handled. This will be by either advertising or scanning to send or receive PDUs (the advertising bearer), or by communicating indirectly with nodes on a mesh network which support the advertising bearer; this is the Generic Attribute Profile (GATT) bearer.

Next is the network layer. This layer processes messages from the bearer layer and defines the network interface over which messages will be sent as well as the message address type and format. It can support multiple bearers.

The lower transport layer takes PDUs from the upper transport layer, where encryption, decryption, and authentication of application data take place. The lower transport layer may perform segmentation and reassembly if required.

Above the upper transport layer is the access layer, which defines the format of application data, defines and controls encryption and decryption performed in the upper transport layer, and verifies the data received from the upper transport layer before forwarding the data.

The foundation model layer implements the configuration and management of a mesh network. Finally, the model layer implements behaviors, messages, and states (e.g. on/off) to define the functionality of a particular element within a node. For example, a Light Emitting Diode (LED) luminaire may have three LED lights. Each light is viewed as one element.

Figure 1: Bluetooth mesh networking is particularly suitable for factory automation. (Source: Bluetooth SIG)

Figure 1: Bluetooth mesh networking is particularly suitable for factory automation. (Source: Bluetooth SIG)

Network Range

Bluetooth SIG has opted for a managed flood message transmission system. Other mesh networks, (for example, ZigBee) use a routed mesh framework, where devices communicate on a defined path. Others, like Thread, use a flooding technique, where every device on the network communicates to every device. Managed flooding controls which device can pass messages. All devices will use Bluetooth Low Energy, but only mains-powered devices will relay messages, saving battery power.

The mesh’s multi-hop communication method extends the range of connections and allows for network scalability, while reducing power consumption due to shorter transmission distances between the nodes.

Emerging Markets

ABI Research predicts nearly one third of the 48 billion Internet-enabled devices installed by 2021 will include Bluetooth, which will find new applications.
“While smartphones and audio accessories remain Bluetooth’s largest markets, the technology is becoming more attractive to low-power IoT applications,” says Andrew Zignani, Industry Analyst at ABI Research. “Though Bluetooth still faces strong competition from the other standards, mesh networking will enable new opportunities for the technology in the smart home, building automation, and emerging IoT markets in which robustness, low latency, scalability, minimal power consumption, and strong security are all additional critical requirements.”

Three characteristics are particularly important for an industrial-grade network: reliability, scalability and security.

Reliability and Scalability

The peer-to-peer communication, where nodes communicate directly with each other, makes Bluetooth mesh connectivity reliable. The structure eliminates the need for a centralized hub or gateway, or routing nodes, so there are no single points of failure. Additionally, its managed flood message relay architecture is inherently multi-path and self-healing.

The Bluetooth mesh is specified to allow up to 32,000 devices, or nodes, per network, sufficient for high density lighting or sensor environments to scale in size as network demands increase.

Building automation uses multicast messaging, where messages are sent to various destinations simultaneously. Bluetooth mesh’s managed flood message relay architecture and the publish/subscribe (send/process) procedure for group messaging are designed to handle the volume of multicast messaging traffic typically found in building automation environments.

Figure 2: Bluetooth’s low power consumption and accessibility are expected to appeal to mesh developers. (Source: Bluetooth SIG)

Figure 2: Bluetooth’s low power consumption and accessibility are expected to appeal to mesh developers. (Source: Bluetooth SIG)

Security

Large wireless device networks present security challenges. These are addressed by Bluetooth mesh technology with several architectural features. First, devices are added to a network using a 256-bit elliptic curve and out-of-band authentication. Within this provisioning process, security measures include an exchange of public keys between the provisioner and the device to be added, followed by authentication of the device and the issue of a security key, or NetKey, to add the device.

In operation, all mesh communication is encrypted and authenticated with 128-bit keys. Encryption and authentication is also implemented on both the network layer and the application layer. Content is secured with a separate application key for end-to-end security.

Each mesh packet is obfuscated so that identifying content is removed from the message. This prevents tracking and is particularly useful when devices move within range of other networks.

Figure 2: Bluetooth’s low power consumption and accessibility are expected to appeal to mesh developers. (Source: Bluetooth SIG)

Figure 3: Silicon companies such as Toshiba Electronics have already announced Bluetooth mesh support in their Bluetooth products. (Source: Toshiba Electronics Europe)

Design Support

Silicon companies are already providing support for the Bluetooth mesh standard. Toshiba Electronics Europe has announced support for its Bluetooth Low Energy products.

Heiner Tendyck, System LSI Marketing Manager, Toshiba Electronics Europe, believes Bluetooth mesh will introduce the technology to new areas. “This standards-based approach means that new untapped markets, such as industrial and commercial, can now leverage ever-present Bluetooth cell phones or tablets to easily control and monitor their systems,” he says.

Silicon Labs has also announced that its Blue Gecko Bluetooth Wireless Starter Kit provides Bluetooth mesh connectivity as well as Bluetooth 5 capability. The company can also provide a Bluetooth mesh stack for Android, allowing smartphones to configure and control nodes on the mesh.


hayes_caroline_115Caroline Hayes has been a journalist covering the electronics sector for more than 20 years. She has worked on several European titles, reporting on a variety of industries, including communications, broadcast and automotive.

Tags: