CWISA-102 Certified Wireless IoT Solutions Administrator Exam
Next scheduled update: CWISA-103 releasing in September 2025
NOTE: For those using the CWSA-101 or CWISA-101 Study and Reference Guides, which are identical in content – only the book title changed to reflect the updated certification name, the current errata is available here.
A solid foundation for the rest of the wireless world. While no certification can cover every single wireless technology in use today, it is important for wireless professionals to grasp the most frequently used wireless solutions in organizations. The Certified Wireless IoT Solutions Administrator (CWISA) learning materials and exam will ensure students know these common wireless certification solutions and prove their knowledge through.
CWISA is built upon two decades of historic quality in WLAN (802.11) certifications and begins the extension of CWNP offerings into the non-802.11 wireless solutions:
Internet of Things (IoT)
Bluetooth Low Energy (BLE)
Cellular Solutions (LTE, LTE-U, 5G, CBRS)
Machine to Machine Communications (M2M)
Zigbee
Location Services
Wired-Side Supporting Technologies
High-Level Awareness of APIs and Automation/Integration Concepts
Project and Program Management Specific to Wireless Solutions Projects
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CWISA-102 2022 Objectives
If you are familiar with the CWNA certification and learning materials, the CWISA will have the same approximate depth and breadth of learning. In the future, additional certifications will address key areas in greater depth, such as automation/integration, IoT, private 5G, etc.
Knowledge Domain Percentage
Wireless Technologies 15%
Radio Frequency Communications 15%
Planning Wireless Solutions 20%
Implementing Wireless Solutions 25%
Supporting Wireless Solutions 25%
1.0 Wireless Technologies (15%)
1.1 Maintain continued awareness of wireless IoT technologies and applications of those technologies
1.1.1 Understand research and lab testing skills to maintain technology awareness
1.1.2 Understand the most common applications of wireless technologies, the frequencies used and communication protocols
1.2 Understand industry standard, certification and regulatory organizations and standards development processes
1.2.1 Institute of Electrical and Electronics Engineers (IEEE)
1.2.2 Internet Engineering Task Force (IETF)
1.2.3 Wi-Fi Alliance
1.2.4 International Telecommunication Union (ITU)
1.2.5 Bluetooth Special Interest Group (SIG)
1.2.6 3rd Generation Partnership Project (3GPP)
1.2.7 Connectivity Standards Alliance (CSA)
1.2.8 LoRa Alliance
1.2.9 Explain the roles of regulatory agencies such as the FCC, IC, CE and others
1.3 Define wireless network types
1.3.1 Wireless Local Area Network (WLAN)
1.3.2 Wireless Personal Area Network (WPAN)
1.3.3 Wireless Body Area Network (WBAN)
1.3.4 Wireless Metropolitan Area Network (WMAN)
1.3.5 Wireless Wide Area Network (WWAN)
1.3.6 Wireless Sensor Network (WSN)
1.3.7 Internet of Things (IoT)
1.3.7.1 Industry 4.0/5.0
1.3.7.2 Connected Vehicles
1.3.7.3 Smart Cities
1.3.7.4 Smart Offices/Buildings/Homes
1.4 Understand hardware and software components of IoT end devices and gateways
1.4.1 Processors
1.4.2 Memory
1.4.3 Radios
1.4.4 Storage
1.4.5 Sensors
1.4.6 Network connections
1.4.7 Operating Systems/Firmware
1.4.8 Application/Service Software
1.4.9 Off-the-shelf Devices
1.4.10 Custom Devices
2.0 Radio Frequency Communications (15%)
2.1 Explain the basic RF wave characteristics, behaviors and measurements used for wireless communications
2.1.1 Frequency, wavelength, amplitude, and phase
2.1.2 Amplification, attenuation, and free space path loss
2.1.3 Absorption, reflection, refraction, scattering, and diffraction
2.1.4 RF signal metrics
2.1.4.1 Watt, milliwatt, and microwatt
2.1.4.2 Decibel (dB) and decibels to milliwatt (dBm)
2.1.4.3 RF noise and noise floor
2.1.4.4 SNR and SINR
2.2 Describe the fundamentals of modulation techniques used in wireless communications
2.2.1 Amplitude Shift Keying (ASK)
2.2.2 Frequency Shift Keying (FSK)
2.2.3 Phase Shift Keying (PSK)
2.2.4 Amplitude and Phase Shift Keying (APSK)
2.2.5 Quadrature Amplitude Modulation (QAM)
2.2.6 Orthogonal Frequency Division Multiplexing (OFDM)
2.2.7 Orthogonal Frequency Division Multiple Access (OFDMA)
2.2.8 Frequency Hopping
2.2.9 Chirp Spread Spectrum (CSS)
2.2.10 Additional modulation methods (AM, FM, and CW)
2.3 Explain the basic capabilities of components used in RF communications
2.3.1 Radios (receivers, transmitters, and transceivers)
2.3.2 Antennas
2.3.3 Intentional radiator and Equivalent Isotropically Radiated Power (EIRP) and Effective Radiated Power (ERP)
2.3.4 RF cabling and connectors
2.3.5 Link types including PTP, PTMP, mesh, ad-hoc and on-demand
2.4 Describe the basic use and capabilities of the RF bands
2.4.1 Radio Frequency Bands
2.4.2 RF bands and communication ranges
2.4.3 RF bands and power levels
3.0 Planning Wireless Solutions (20%)
3.1 Identify and use the wireless IoT system requirements
3.1.1 Use cases and applications
3.1.2 Capacity requirements
3.1.3 Security and monitoring requirements
3.1.4 Integration requirements (automation, data transfer/conversion, APIs, cross-platform integration)
3.1.5 Stakeholder identification
3.2 Identify and comply with system constraints
3.2.1 Budgetary constraints
3.2.2 Security constraints
3.2.3 Technical constraints
3.2.4 Business policies and requirements
3.2.5 Regulatory constraints
3.2.6 System dependencies
3.2.7 Evaluate existing network infrastructure and understand its limitations in the context of the new wireless system
3.3 Select appropriate wireless IoT solutions based on requirements and constraints
3.4 Plan for the technical requirements of the wireless IoT solution
3.4.1 LAN networking requirements (VLANs, PoE, TCP/IP, DHCP, DNS, wired connectivity, cellular connections, serial data)
3.4.2 WAN networking requirements
3.4.3 Systems requirements (virtualization, containers, cloud platforms, cabling, grounding, radios, antennas)
3.4.4 APIs, protocols, and programmability (RESTful, Webhooks, Web Sockets, OpenConfig, MQTT)
3.4.5 Frequency coordination compliance (channel capacity management, interoperability, interference management)
3.5 Understand the basic features and capabilities of common wireless IoT solutions and plan for their implementation
3.5.1 Internet of Things (IoT) (CO-to-CO, CO-to-Service, CO-to-human)
3.5.2 802.11 WLANs
3.5.3 Bluetooth
3.5.4 Zigbee
3.5.5 802.15.4-based protocols
3.5.6 LoRaWAN
3.5.7 Sigfox
3.5.8 Location services (RTLS, Bluedot, geofencing, beaconing) and location methods, including triangulation, trilateration and multi-lateration
4.0 Implementing Wireless Solutions (25%)
4.1 Understand the wireless IoT solution and consider key issues related to automation, integration, monitoring, and management
4.1.1 Automation, integration, and management protocols and standards (APIs, programming languages, data structures, communication protocols, data of interest, analytics, and services)
4.1.2 Monitoring solutions (integrated, overlay, APIs)
4.2 Use best practices in wireless IoT solution implementations
4.2.1 Pilot testing (proof-of-concept, early-stage analysis)
4.2.2 Configuration and staging
4.2.3 Installation
4.2.4 Documentation
4.3 Validate wireless solution implementations including RF communications and application functionality
4.3.1 Initial testing
4.3.2 Troubleshooting and remediation
4.4 Understand and implement basic installation procedures
4.4.1 Configure and mount wireless equipment according to applicable safety requirements (OSHA) and building codes
4.4.2 Configure connectivity (wireless and wired)
4.4.3 Configure the network infrastructure or communicate configuration requirements to the appropriate individuals
4.4.4 Configure cloud connectivity where appropriate
4.4.5 Configure features related to video, voice, captive portals, container-based apps, telemetry, location services, MDM and SDN/NFV
4.4.6 Implement appropriate security solutions for the selected wireless system
4.4.6.1 Authentication
4.4.6.2 Authorization
4.4.6.3 Encryption
4.4.6.4 Monitoring
4.5 Implement best practices in knowledge transfer and hand-off
4.5.1 Staff training (end users, administrators)
4.5.2 Solution documentation (topology, configuration, protocols, physical locations, APIs in use)
4.5.3 Final customer meeting (requirements review, stakeholder approval)
5.0 Supporting Wireless Solutions (25%)
5.1 Administer the wireless solution while considering the implications of various vertical markets
5.1.1 Healthcare
5.1.2 Industrial/Manufacturing
5.1.3 Smart Cities
5.1.4 Consumer spaces (smart homes)
5.1.5 Smart Agro
5.1.6 Smart Offices/Buildings
5.1.7 Retail
5.1.8 Education
5.1.9 Large Public Venues
5.2 Troubleshoot common problems in wireless IoT solutions
5.2.1 Interference
5.2.2 Improper configuration
5.2.3 Security misconfiguration
5.2.4 Signal strength
5.2.5 Malfunctioning hardware
5.2.6 Software/firmware issues
5.2.7 Drivers
5.2.8 Faulty custom software code
5.2.9 Faulty installation
5.3 Understand and determine the best use of scripting and programming solutions for wireless IoT implementations
5.3.1 Identify and differentiate among the features of various scripting/programming languages (Python, R, PHP, C (and variants), JavaScript, Java and TypeScript)
5.3.2 Understand the basics of data structures commonly used for integration of networked systems
5.3.2.1 JSON
5.3.2.2 YANG
5.3.2.3 XML
5.3.2.4 YAML
5.3.2.5 XAML
5.3.3 Understand the basics of APIs and common models
5.3.3.1 RESTful
5.3.3.2 webhooks
5.3.3.3 WebSockets
5.3.3.4 Standard HTTP GET/POST processing
5.3.4 Understand the basics of networking, application and security protocols used in wireless IoT solutions
5.3.4.1 HTTP/HTTPS
5.3.4.2 NETCONF
5.3.4.3 OpenConfig
5.3.4.4 MQTT, DDS, AMQP, CoAP
5.3.4.5 SNMP
5.3.4.6 SSL/TLS
5.3.4.7 SSH
5.3.4.8 IPv4/IPv6
5.3.4.9 TCP/UDP
5.4 Understand application architectures and their impact on wireless IoT solutions
5.4.1 Single-tier architecture
5.4.2 Multi-tier architecture
5.4.3 Database systems (relational, No-SQL, streaming data)
5.4.4 Web Servers
5.4.5 Application servers/services (Network Time Protocol, DNS, system-specific)
Sample Questions Answers
QUESTION 1
What part(s) of the OSI network model does the IETF primarily focus on for the development of standards?
A. Physical Layerand above
B. All layers
C. Network Layer and above
D. Data Link Layer
Answer: C
Explanation:
IETF’s Focus: The Internet Engineering Task Force (IETF) primarily develops and standardizes internet
protocols operating at the Network Layer (Layer 3) and above in the OSI model.
Key Protocols: Some prominent IETF-developed protocols include:
IP (Internet Protocol): Foundation of internet addressing and routing.
TCP (Transmission Control Protocol): Reliable, connection-oriented data transport.
UDP (User Datagram Protocol): Connectionless, best-effort data transport.
DNS (Domain Name System): Translates domain names into IP addresses.
HTTP (Hypertext Transfer Protocol): Web communication.
References
QUESTION 2
What organization maintains and publishes the 802.15.4 Standard?
A. Bluetooth SIG
B. IEEE
C. IETF
D. Zigbee Alliance
Answer: B
Explanation:
IEEE 802.15.4: The IEEE 802.15.4 standard is a fundamental specification for low-rate wireless
personal area networks (LR-WPANs). It serves as the basis for many wireless IoT protocols.
IEEE’s Role: The Institute of Electrical and Electronics Engineers (IEEE) is the organization responsible
for creating, maintaining, and publishing the 802.15.4 standard.
QUESTION 3
What is the most common difference between a single board computer (SBC) and a controller board?
A. SBCs typically have connectors for display and input devices while controller boards do not
B. Controller boards have I/O headers and SBCs do not
C. SBCs always have connectors for M2 devices and controller boards do not
D. Controller boards have more powerful processors than most SBCs
Answer: A
Explanation:
SBCs (Single Board Computers): Designed as standalone, small-form-factor computers.
They often include:
Display Interfaces: HDMI, DisplayPort, etc.
Input Connections: USB for keyboards, mice, etc.
General Purpose Functionality: Can run a full operating system for wider applications.
Controller Boards: Focus on controlling specific hardware or systems.
Limited direct I/O: Limited connectors for displays/input devices.
Specialized tasks: Designed for embedded applications within larger systems.
QUESTION 4
You are considering the implementation of a lab for testing wireless equipment. What is the primary benefit of such a lab? (Choose the single best answer.)
A. Provides for testing to determine how much RF exposure you can tolerate
B. Provides a failover environment for your production systems
C. Provides a way to repurpose old hardware that is not ready for final removal
D. Provides a safe environment in which to develop practical skills and knowledge of a technology and to test the technology
Answer: D
Explanation:
Lab Purpose: Wireless testing labs offer controlled settings to:
Skill Development: Hone practical understanding of wireless technologies without impacting
production environments.
Experimentation: Safely test different configurations, compatibility, and potential issues.
Troubleshooting: Isolate problems, test solutions, and understand how equipment behaves in various
scenarios.
Other Benefits (While not the primary benefit):
Learning Environment: Ideal for structured training and exploration.
Evaluation: Compare hardware performance before deployment.
References
Benefits of IT Labs: Can be extended from wireless to broader IT experimentation and learning.
(Articles on this topic are readily available)
QUESTION 5
What is the typical range of a wireless body area network (WBAN)?
A. 1-2 meters
B. 10 square meters
C. 10 centimeters
D. 10 meters
Answer: A
Explanation:
WBAN Range: Wireless Body Area Networks (WBANs) specialize in short-range communication
around the human body. Typical ranges fall within 1-2 meters.
Purpose: This range is designed to:
Connect sensors monitoring health metrics.
Transmit data to a central coordinator device (e.g., smartphone).
Minimize interference potential with other wireless networks.
QUESTION 6
What software is typically stored in ROM and is used to initialize a device?
A. Firmware
B. Application
C. Container
D. Service
Answer: A
Explanation:
Firmware Definition: Firmware is a type of software embedded in hardware devices. It provides lowlevel
instructions that control the basic operations and initialization of the device.
ROM Storage: Firmware is typically stored in Read-Only Memory (ROM) or other forms of nonvolatile
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