Buffl

Lecture Notes Access Technologies

CF
von Carmen F.

WiFi-HaLow

sub 1 GHz

improved transmission range

connecting endpoints such as fog computing nodes, high-data-rate sensors, and audio or video analytics devices or for deploying Wi-Fi backhaul infrastructures

main use cases

  • Sensors and meters covering a smart grid

  • Backhaul aggregation of industrial sensors and meter data

  • Extended range Wi-Fi

star topology, but includes a simple hop relay

MAC enhancments:

  • Number of devices: Has been scaled up to 8192 per access point.

  • MAC header: Has been shortened to allow more cient communication.

  • Null data packet (NDP) support: Is extended to cover several control and management frames. Relevant information is concentrated in the PHY header and the additional overhead associated with decoding the MAC header and data payload is avoided. This change makes the control frame exchanges cient and less power-consuming for the receiving stations.

  • Grouping and sectorization: Enables an AP to use sector antennas and also group stations (distributing a group ID). In combination with RAW and TWT, this mechanism reduces contention in large cells with many clients by restricting which group, in which sector, can contend during which time window. (Sectors are described in more detail in the following section.)

  • Restricted access window (RAW): Is a control algorithm that avoids simultaneous transmissions when many devices are present and provides fair access to the wireless network. By providing more client access to the medium, additional power savings for battery-powered devices can be achieved, and collisions are reduced.

  • Target wake time (TWT): Reduces energy consumption by permitting an access point to down times when a device can access the network. This allows devices to enter a low-power state until their TWT time arrives. It also reduces the probability of collisions in large cells with many clients.

  • Speed frame exchange: Enables an AP and endpoint to exchange frames during a reserved transmit opportunity (TXOP). This reduces contention on the medium, minimizes the number of frame exchanges to improve channel eficiency, and extends battery life by keeping awake times short.


IEEE 802.15.1, Bluetooth

wireless technology standard

exchanging data between xed and mobile

devices over short distances using short-wavelength radio waves in the industrial, scientifc and medical radio bands, from 2.402 GHz to 2.480 GHz

wireless alternative to RS-232 data cables

Bluetooth Core Specifcation [Bluetooth Core, 2019] defnes the technology building blocks

specifcation is overseen by the Bluetooth Special Interest Group

[Bluetooth Mesh, 2019] define requirements to enable an interoperable many-to-many mesh networking solution for Bluetooth Low Energy (LE) wireless technology suited for control, monitoring, and automation systems where tens, hundreds, or thousands of devices need to reliably and securely communicate with one another.

uses a radio technology called frequency-hopping spread spectrum (FHSS)Bluetooth divides transmitted data into packets, and transmits each packet on one of 79 designated Bluetooth channels. Each channel has a bandwidth of 1 MHz. It usually performs 1600 hops per second, with adaptive frequency-hopping (AFH) enabled. Bluetooth Low Energy uses 2 MHz spacing, which accommodates 40 channels.

packet-based protocol with a master/worker architecture. One master may communicate with up to seven workers

All devices within a given piconet use the clock provided by the master as the base for packet exchange. clock ticks with a period of 312.5 µs

in the simple case of single-slot packets, the master transmits in even slots and

receives in odd slots

not have to be in visual line of sight of each other; however, a quasi optical wireless path must be viable

effective range varies depending on propagation conditions, material coverage, production

sample variations, antenna confgurations and battery conditions.

lower-powered device tends to set the range limit.

include device discovery, connection establishment and connection mechanisms

Devices implementing both systems (BR and LE) can communicate with other devices implementing both systems as well as devices implementing either system.

Low Energy Operation

lower data rates and has lower duty cycles then BR

isochronous data transfer in a connection-oriented and connectionless mechanism

unlicensed 2.4 GHz ISM band.

frequency hopping transceiver to combat interference and fading

mandatory symbol rate is 1 megasymbol per second (Msym/s), where 1 symbol represents 1 bit therefore supporting a bit rate of 1 megabit per second (Mb/s), which is referred to as the LE 1M PHY.

two coding schemes: S=2, where 2 symbols represent 1 bit therefore supporting a bit rate of 500 kb/s, and S=8, where 8 symbols represent 1 bit therefore supporting a bit rate of 125 kb/s.

FDMA TDMA Forty (40) physical channels, separated by 2 MHz, are used in the FDMA scheme. Three (3) are used as primary advertising channels and 37 are used as general purpose channels (including as secondary advertising channels). A TDMA based polling scheme is used in which one device transmits a packet at a predetermined time and a corresponding device responds with a packet after a predetermined interval.

LE uses a randomly generated Access Address to identify a

physical channel between devices.

piconet physical channel is used for communication between connected devices and is associated with a specifc piconet

advertising physical channel is used for broadcasting advertisements to LE devices

periodic physical channel is used to send user data to scanner devices in periodic advertisements at a specifed interval

isochronous physical channel is used to transfer isochronous data between LE devices in an LE piconet or to transfer isochronous data between unconnected LE devices.

BT Mesh Features

All nodes have the ability to transmit and receive mesh messages.

Nodes can also optionally support one or more additional features:

  • Relay feature - the ability to receive and retransmit mesh messages over the advertising bearer to enable larger networks.

  • Proxy feature - the ability to receive and retransmit mesh messages between GATT and advertising bearers.

  • Low Power feature - the ability to operate within a mesh network at signifcantly reduced receiver duty cycles only in conjunction with a node supporting the Friend feature.

  • Friend feature - the ability to help a node supporting the Low Power feature to operate by storing messages destined for those nodes.

A node that supports a feature may have that feature enabled or disabled, and the feature, when enabled, may be or may not be in use

A node that supports the Relay feature and has the Relay feature enabled is known as a Relay node

A node that supports the Proxy feature and has the Proxy feature enabled is known as a Proxy node

A node supporting the Low Power feature cannot have this feature disabled and must establish a friendship with another node supporting the Friend feature before it can use the Low Power feature to reduce receiver duty cycles. A node that supports the Low Power feature and has a friendship with a node that supports the Friend feature is known as a Low Power node

A node that supports the Friend feature, has the Friend feature enabled, and has a friendship with a node that supports the Low Power feature is known as a Friend node.

Author

Carmen F.

Informationen

Zuletzt geändert