12. Short-Range Wireless Technologies – Telecommunications and Networking (2024)

Chapter Objectives

12-1 Describe the characteristics and functions of various short-range wireless technologies, such as Bluetooth, Wi-Fi, Zigbee, Z-Wave, UWB, and NFC.
12-2 Compare the advantages and disadvantages of various short-range wireless technologies in terms of data rate, range, power consumption, latency, accuracy, security, and interoperability.
12-3 Summarize the underlying principles and mechanisms of short-range wireless technologies, such as radio waves, frequency bands, modulation schemes, multiplexing techniques, and protocols.
12-4 Evaluate the performance and quality of service of short-range wireless technologies using metrics such as throughput, delay, jitter, packet loss, bit error rate, and signal-to-noise ratio.
12-5 Identify the challenges and opportunities of short-range wireless technologies in the context of emerging trends and technologies, such as IoT, 5G, AI, and cloud computing.

Wireless short-range technologies enable communication between electronic devices over a distance of up to 100 meters, depending on the power and version of the device. Wireless short-range technologies offer various benefits, such as convenience, mobility, low cost, and low power consumption. Wireless short-range technologies can also support different applications, such as data transfer, streaming, location tracking, and device control. We outline some the most common wireless short-range technologies in this chapter, including Bluetooth, Wi-Fi, Zigbee, and NFC.

Bluetooth is a wireless technology that allows devices to communicate over short distances (typically up to 10 m) using low-power radio waves. Bluetooth enables short-range data and voice communication between devices, such as smartphones, headphones, speakers, laptops, printers, and medical equipment. Bluetooth supports various protocols and profiles to provide different services, such as audio streaming, file transfer, device positioning, and internet access. Bluetooth is managed by the Bluetooth Special Interest Group (SIG), which oversees the development of the specification, the qualification program, and the trademark protection.

Bluetooth operates in the 2.4 GHz unlicensed industrial, scientific, and medical (ISM) frequency band, using frequency-hopping spread spectrum (FHSS) to avoid interference and increase security. FHSS divides the data into packets and hops between 79 channels, each with a bandwidth of 1 MHz, at a rate of 1600 hops per second. Bluetooth devices also use adaptive frequency-hopping (AFH) to detect and avoid channels that are occupied by other wireless technologies, such as Wi-Fi.

Bluetooth devices can form personal area networks (PANs) with different topologies, such as point-to-point, point-to-multipoint, broadcast, and mesh. Bluetooth devices can also support different features and functionalities, depending on their version and profile. The version refers to the specification of the Bluetooth technology, which defines the physical layer, the link layer, and the protocol stack. The profile refers to the application layer, which defines the roles and services that Bluetooth devices can offer. Some of the most common Bluetooth versions and profiles are:

Bluetooth Classic: This is the original version of Bluetooth, which supports data rates of up to 3 Mbps and is mainly used for streaming audio and data transfer applications. Some of the profiles that Bluetooth Classic supports are Advanced Audio Distribution Profile (A2DP), Hands-Free Profile (HFP), and Serial Port Profile (SPP).
Bluetooth Low Energy (LE): This is a newer version of Bluetooth, which supports data rates of up to 2 Mbps and is designed for low power consumption and long battery life. Bluetooth LE is mainly used for device communication and positioning applications. Some of the profiles that Bluetooth LE supports are Generic Attribute Profile (GATT), Device Information Service (DIS), and Proximity Profile (PXP).
Bluetooth 5: This is the latest version of Bluetooth, which supports data rates of up to 50 Mbps and offers four times the range and eight times the broadcast capacity of Bluetooth 4.2. Bluetooth 5 also introduces new features, such as direction finding and long range mode, which enable high accuracy indoor location services and extended outdoor coverage.

To find out more about Bluetooth, visit the Bluetooth website: https://www.bluetooth.com/learn-about-bluetooth/tech-overview/.

Wi-Fi typically operates within a range of up to 100 meters indoors and up to 300 meters outdoors, depending on the power and version of the Wi-Fi device. However, Wi-Fi range can be affected by various factors, such as obstacles, interference, antenna design, and environmental conditions.

Wi-Fi has evolved over the years to offer higher data rates, lower power consumption, and improved security and reliability. Wi-Fi is also compatible with the Internet Protocol (IP), which means that Wi-Fi devices can easily access the Internet and communicate with other IP-based devices. Let’s review the most common Wi-Fi versions:

Wi-Fi 4 (IEEE 802.11n): This version supports data rates of up to 600 Mbps and operates in both 2.4 GHz and 5 GHz bands.It also introduces multiple-input multiple-output (MIMO) technology, which uses multiple antennas to increase throughput and range 1 2
Wi-Fi 5 (IEEE 802.11ac): This version supports data rates of up to 3.5 Gbps and operates only in the 5 GHz band.It also uses wider channels, more spatial streams, and beamforming technology, which directs the radio signal to the intended receiver
Wi-Fi 6 (IEEE 802.11ax): This version supports data rates of up to 10 Gbps and operates in both 2.4 GHz and 5 GHz bands. It also uses orthogonal frequency-division multiple access (OFDMA), which divides the channel into smaller subchannels to accommodate more devices and reduce latency.
Wi-Fi 7 is the next-generation wireless standard, which is set to supersede Wi-Fi 6E. Wi-Fi 7, officially known as 802.11be, builds on the foundation laid forth by Wi-Fi 6E. That means that it supports 2.4 GHz, 5 GHz, and 6 GHz wireless bands. Below are some of its proposed features:
- A maximum channel bandwidth of 320 MHz, which is double the bandwidth of Wi-Fi 6E
- Up to 16 spatial streams and multiple-input multiple-output (MIMO) technology, which uses multiple antennas to increase throughput and range
- 4096-QAM (4K-QAM) modulation, which enables each symbol to carry 12 bits rather than 10 bits, resulting in 20% higher theoretical transmission rates than Wi-Fi 6E’s 1024-QAM
- Multi-link operation (MLO), which allows a device to simultaneously send and receive data across different frequency bands and channels, increasing capacity and reducing latency
- Flexible channel utilization, which enables a device to avoid interference by blocking off a portion of the channel that is impacted, while continuing to use the rest of the channel
- A theoretical maximum data rate of 46 Gbps, which is nearly five times faster than Wi-Fi 6E’s 9.6 Gbps

Wi-Fi 7 is still in the draft specifications phase and hasn’t been officially certified by the Wi-Fi: https://www.wi-fi.org/who-we-are/current-work-areas#Wi-Fi%207.

Zigbee is a wireless technology that enables low-power, low-data-rate, and low-cost communication between devices. Zigbee is based on the IEEE 802.15.4 standard and operates in the 2.4 GHz band. Zigbee is mainly used for IoT applications, such as smart home, smart lighting, smart metering, and industrial automation. Zigbee supports mesh networking, which allows devices to relay messages to each other and extend the network coverage.

Zigbee operates in the industrial, scientific, and medical (ISM) radio bands, which are unlicensed and available worldwide. Zigbee devices can transmit data over distances of up to 100 meters indoors and 300 meters outdoors, depending on the power output and environmental conditions. Zigbee is mainly used for low-bandwidth applications that require long battery life and secure networking. Zigbee is also compatible with the Internet Protocol (IP), and devices can communicate with each other in different modes, depending on their roles and capabilities.

Zigbee devices can also support different features and functionalities, depending on their version and profile. The version refers to the specification of the Zigbee technology, which defines the protocols and parameters of the wireless network. The profile refers to the application of the Zigbee technology, which defines the roles and services that Zigbee devices can offer. Some of the most common Zigbee versions and profiles are listed below:

Zigbee 2007: This is the original version of Zigbee, which supports data rates of up to 250 kbps and is mainly used for home automation, lighting control, and security applications. Some of the profiles that Zigbee 2007 supports are Home Automation Profile (HAP), Commercial Building Automation Profile (CBAP), and Smart Energy Profile (SEP).
Zigbee PRO: This is an enhanced version of Zigbee, which supports data rates of up to 250 kbps and offers improved security, reliability, and network management. Zigbee PRO is mainly used for industrial, commercial, and residential applications. Some of the profiles that Zigbee PRO supports are Zigbee Light Link (ZLL), Zigbee Green Power (ZGP), and Zigbee IP (ZIP).
Zigbee 3.0: This is the latest version of Zigbee, which supports data rates of up to 250 kbps and offers backward compatibility with previous Zigbee versions and profiles. Zigbee 3.0 is designed to unify the Zigbee ecosystem and enable interoperability among Zigbee devices from different manufacturers and applications.

To find out more about Zigbee, visit the Connectivity Standards Alliance website: https://csa-iot.org/.

Z-Wave also operates in the industrial, scientific, and medical (ISM) radio bands. Z-Wave devices can use the 800-900 MHz frequency band, which has 16 channels and a data rate of up to 100 kbps. Z-Wave devices can transmit data over distances of up to 100 meters indoors and 800 meters outdoors, depending on the power output and environmental conditions. Z-Wave devices can communicate in different modes, such as point-to-point, broadcast, and mesh, and is compatible with the Internet Protocol (IP).

Z-Wave has various applications in different domains, such as home automation, lighting control, security systems, smart energy, and smart health. Z-Wave is promoted and standardized by the Z-Wave Alliance, which certifies device compliance and interoperability. Z-Wave is also supported by the GSMA group, which defines a platform for the deployment of Z-Wave standards within mobile handsets.

Z-Wave has evolved over the years to offer higher performance, lower power consumption, and improved security and reliability. The latest Z-Wave version is the 700 series, which supports data rates of up to 100 kbps and offers backward compatibility with previous Z-Wave versions and profiles. Z-Wave 700 series also introduces new features, such as extended battery life, increased range, and enhanced security. How is Z-Wave different than Zigbee? Find out in this Spiceworks article (2022): Zigbee vs. Z-wave: Key Differences (spiceworks.com).

UWB is a wireless technology that uses very low energy pulses of radio waves to transmit data and measure the location and direction of objects with high accuracy. UWB can operate over a large portion of the radio spectrum, typically from 3.1 GHz to 10.6 GHz, and can co-exist with other wireless technologies, such as Wi-Fi, Bluetooth, and NFC, without causing interference. Below are some benefits of using UWB:

High data rates of up to 1 Gbps within a 10-meter radius, which is suitable for wireless personal area network (WPAN) applications, such as streaming video, audio, and data
Low power consumption with very short pulses of radio waves and the ability to switch between active and idle modes to save battery life
High precision with nanosecond accuracy, which determines the distance and angle of arrival of the signals with centimeter accuracy
Enhanced spatial resolution and range with multiple antennas and channels
Robustness with frequency-hopping and adaptive techniques, and less jamming and eavesdropping through using encryption and authentication methods.

Some applications of UWB include real-time location tracking, geofencing, secure digital vehicle keys, and smart home devices such as lights, thermostats, and security systems, by using gestures and voice commands.

To find out more about UBW, read this article by Android Authority:

What is UWB used for in phones? Ultra wideband technology, explained (androidauthority.com)

Near-field communication (NFC) is a wireless technology that enables communication between two electronic devices over a distance of 4 cm (1.57 in) or less. NFC offers a low-speed connection through a simple setup that can be used to bootstrap more capable wireless connections. NFC is based on existing radio-frequency identification (RFID) standards, such as ISO/IEC 14443 and FeliCa, and uses the 13.56 MHz frequency band to transmit data and voice signals at data rates ranging from 106 to 848 kbit/s. NFC devices can also communicate in different modes, such as point-to-point, broadcast, and mesh, depending on their roles and capabilities, and is compatible with the Internet Protocol (IP).

NFC has various applications in different domains, such as contactless transactions, data exchange, and simplified setup of more complex communications, such as Wi-Fi. NFC can also provide high-precision location tracking and secure digital keys for automotive and smart home devices. NFC is promoted and standardized by the NFC Forum, which certifies device compliance and interoperability. NFC is also supported by the GSMA group, which defines a platform for the deployment of NFC standards within mobile handsets.To learn more about NFC, visit the NFC Forum’s website: https://nfc-forum.org/.

Concepts Corner

Bluetooth,Zigbee,Z-Wave, andUltra-Wideband (UWB) each have unique characteristics with real-life applications. A few are listed below.

Bluetooth is widely used for personal area networks, offering moderate data rates and low power consumption, and known for audio streaming and device connectivity. Products include wireless headphones like the Apple AirPods and fitness trackers like the Fitbit.
Zigbeeis designed for low-power, low-data rate applications, making it perfect for home automation and IoT devices.Products using Zigbee include the Philips Hue smart lighting system and the Amazon Echo Plus, which acts as a smart home hub.
Z-Wavealso targets home automation, providing reliable, low-latency communication with a slightly longer range than Zigbee.Examples of Z-Wave products are the Samsung SmartThings Hub and the Yale Assure Lock.
UWB stands out with its high data rates and precise location tracking capabilities, suitable for applications requiring high accuracy and low latency.Products using UWB include the Apple AirTag for item tracking and the Samsung Galaxy Note20 Ultra, which uses UWB for enhanced spatial awareness and file sharing.
NFC is known for its ease of use in close-proximity applications, such as contactless payments and access control. Products using NFC include smartphones like the iPhone and Samsung Galaxy series for mobile payments (Apple Pay, Google Wallet), contactless credit and debit cards, and smartwatches such as the Apple Watch for quick transactions.

Comparison of Wireless WPAN Performace

The performance of a WPAN can be measured in terms of data coding efficiency, transmission time, and power handling capabilities. A comparison has been made with respect to transmission time, data coding efficiency and power handling of four short-range wireless communication technologies namely, Bluetooth, ZigBee Ultra-wideband, and Wi-Fi.

Wireless technology	Bluetooth	Zigbee	Wi-Fi	UWB
Time of bits (μs)	4	802.15.1	0.01825	0.009
Data rate (M bitss)	0.72	0.25	54	110
Maximum data size	339 (DH5)	102	2312	2044
Maximum overhead size	1588	31	58	42
Code efficiency %	94.41	76.52	97.18	97.94

Table 12-1: Comparison of WPAN technologies

Mubashar, R., Siddique, M.A.B., Rehman, A.U.et al.Comparative performance analysis of short-range wireless protocols for wireless personal area network.Iran J Comput Sci4, 201–210 (2021). https://doi.org/10.1007/s42044-021-00087-1.

For another comparison of short-range wireless technologies, watch this Automate Your Life video (2021) [48:36]

ZigBee vs Z-Wave vs Wi-Fi vs Thread vs Bluetooth vs Matter (CHIP)

Source: S. Cao, X. Chen, and B. Yuan, “Overview of Short-range Wireless Communication Protocols,” in 2022 7th International Conference on Computer and Communication Systems (ICCCS), Apr. 2022, pp. 519–523. doi: 10.1109/ICCCS55155.2022.9846125. Available: https://ieeexplore.ieee.org/document/9846125.

Artifical Intelligence of Things (AIoT)

AIOT (Artificial Intelligence of Things) merges AI’s data analysis and learning capabilities with wireless technologies and IoT’s connectivity and data-gathering features. This integration enhances data processing, decision-making, and automation in various applications, such as smart homes, healthcare, and industrial automation. For example, in smart homes, AIOT can optimize energy usage by learning residents’ habits and adjusting settings accordingly. In healthcare, AIOT devices can monitor patients in real-time, providing critical data for early diagnosis and personalized treatment plans. Industrial automation benefits from AIOT by enabling predictive maintenance and improving operational efficiency through real-time data analysis.

However, implementing AIOT comes with challenges such as ensuring data privacy, security, and the need for robust infrastructure. Data privacy is a significant concern as AIOT systems collect vast amounts of personal data, necessitating stringent security measures to protect against breaches. Additionally, the development of standards and frameworks is crucial for ensuring interoperability and scalability of AIOT systems. This involves creating protocols that allow different devices and systems to communicate seamlessly.While AIOT holds great promise for creating smarter, more efficient environments, careful planning and management are essential to address its complexities and maximize its potential.

Source: Seng KP, Ang LM, Ngharamike E. Artificial intelligence Internet of Things: A new paradigm of distributed sensor networks. International Journal of Distributed Sensor Networks. 2022;18(3). doi:10.1177/15501477211062835.

Discussion Topics

Short-range wireless technologies are popular for everyday consumers. What are some of the issues associated with these?

Data Privacy and Security: How can you ensure your data privacy and security when using short-range wireless technologies like Bluetooth and Wi-Fi on campus or in your apartment complex? What are the risks and what measures that can be taken to mitigate these risks?
Convenience vs. Cost: Short-range wireless technologies offer significant convenience for students, such as easy connectivity and mobility. However, these technologies can also come with costs, both financial and in terms of battery consumption. How do you balance the convenience of these technologies with the associated costs? Are there specific strategies or tools that can help manage this balance effectively?
Short-Range Wireless and Mental Well-Being: What do you consider as best practices when adopting the use of short-range wireless technologies? When would you recommend using which technologies for different scenarios, such as academic work, social interactions, and personal entertainment, and how would you use or limit the use of short-range wireless for increased well-being?