13 Courses
Wireless Communication
Bluetooth 5.3
Duration: 14 Hours (7 Days, 2 Hours per Day)
Format: Live Webinar
Course Overview
Bluetooth is the leading wireless technology for hands-free communication, IoT, and high-quality audio streaming. Bluetooth 5.3 introduces enhanced security, adaptive frequency hopping, isochronous channels, and dynamic power control, making it more efficient for modern wireless applications.
This course provides an in-depth understanding of Bluetooth Low Energy (BLE) Core Specification 5.3, including:
Protocol stack architecture and Bluetooth Classic vs. BLE.
Advanced BLE features such as direction finding, multi-stream audio, and EATT.
Security and authentication mechanisms to protect against cyber threats.
Hands-on implementation of Bluetooth applications on Android devices.
Who Should Attend?
Wireless Engineers – Implementing BLE communication systems.
Embedded System Developers – Developing Bluetooth-enabled IoT devices.
Android Developers – Working with Bluetooth APIs & app integration.
RF & Audio Engineers – Optimizing Bluetooth audio streaming.
IoT & Automotive Engineers – Designing in-car Bluetooth infotainment systems.
Security Engineers – Implementing Bluetooth authentication and encryption.
Why Choose This Course?
Covers BLE security, Bluetooth 5.3 features, and RF performance optimization.
Hands-on training with Android Studio, Wireshark, and BLE debugging tools.
Learn how to develop, optimize, and troubleshoot Bluetooth systems.
Pre-requisites
Basic understanding of wireless communication protocols.
Familiarity with Bluetooth, embedded systems, or Android development (recommended).
Lab Setup
Development Tools:
Android Studio for Bluetooth app development.
Wireshark & btmon for Bluetooth packet analysis.
Bluetooth Debugging Tools (btsnoop, QXDM, ADB logs).
Hardware Requirements:
Android development board (Pixel, Raspberry Pi running AOSP).
Bluetooth Low Energy (BLE) development kit.
Wireless Communication
Wi-Fi 11ac
Duration: 2 Days (14 Hours)
Level: Intermediate
Course Overview
Wi-Fi 5, based on the 802.11ac standard, significantly improves wireless speed, capacity, and reliability compared to previous generations. This course provides an in-depth understanding of Wi-Fi 5 technology, covering its PHY and MAC layer enhancements, MIMO, Beamforming, MU-MIMO, and Channel Bonding techniques.
Participants will gain hands-on experience in Wi-Fi 5 network design, deployment, optimization, and troubleshooting using industry tools like Wireshark, Ekahau, and AirMagnet. The course will also compare Wi-Fi 5 vs. Wi-Fi 6, preparing participants for next-generation wireless networks.
Who Should Attend?
Network Engineers & Architects – Designing & optimizing Wi-Fi 5 networks.
Telecom & ISP Professionals – Deploying 802.11ac in enterprise environments.
IT Administrators – Managing high-speed wireless networks.
Wireless Engineers & RF Specialists – Understanding MIMO, Beamforming, and DFS.
Why Choose This Course?
Covers Wi-Fi 5 PHY & MAC Layer Enhancements, MIMO, Beamforming, and Channel Bonding.
Hands-on training with Wireshark, Ekahau, and real-time Wi-Fi 5 analysis.
Learn Wi-Fi 5 security, deployment best practices, and troubleshooting techniques.
Pre-requisites
Basic knowledge of wireless networking & previous Wi-Fi standards (802.11a/b/g/n).
Familiarity with IP networking, VLANs, and QoS
Wireless Communication
Wi-Fi 1ax
Duration: 3 Days (21 Hours)
Level: Intermediate to Advanced
Course Overview
Wi-Fi 6, based on the 802.11ax standard, is the latest evolution in wireless networking, designed to provide higher efficiency, lower latency, and improved performance in dense environments. This course provides an in-depth understanding of Wi-Fi 6 (802.11ax) features, architecture, and deployment strategies.
Participants will gain hands-on experience in OFDMA, MU-MIMO, BSS Coloring, TWT (Target Wake Time), and Wi-Fi 6 security mechanisms. The training also covers network design, optimization, and real-world troubleshooting to ensure maximum throughput, reliability, and QoS in enterprise and consumer networks.
Who Should Attend?
Network Engineers & Architects – Designing & optimizing Wi-Fi 6 networks.
Telecom & ISP Professionals – Deploying Wi-Fi 6 in large-scale environments.
IT Administrators – Managing enterprise Wi-Fi networks.
RF & Wireless Engineers – Understanding PHY & MAC layer improvements.
IoT & Embedded Engineers – Integrating Wi-Fi 6 into smart devices.
Why Choose This Course?
Covers Wi-Fi 6 PHY & MAC Layer Enhancements, OFDMA, MU-MIMO, BSS Coloring.
Hands-on training with Wireshark, Ekahau, and real-time Wi-Fi 6 analysis.
Learn Wi-Fi 6 security, deployment best practices, and network troubleshooting.
Pre-requisites
Basic understanding of wireless networking & Wi-Fi standards.
Familiarity with IP networking, VLANs, and QoS concepts.
Wireless Communication
Wi-Fi
Duration: 21 Hours (3 Days)
Level: Intermediate to Advanced
Course Overview
This course provides an in-depth understanding of Wi-Fi technologies, covering 802.11 standards, frequency bands, multi-antenna systems, and next-generation Wi-Fi (802.11ax & 802.11be). Participants will gain expertise in Wi-Fi security, power management, beamforming, and performance optimization, along with practical knowledge of network deployments, interference mitigation, and coexistence with LTE-U.
Learning Outcomes
By the end of this course, participants will:
Understand Wi-Fi data rates, spectral efficiency, and network evolution.
Learn about 802.11n, 802.11ac, 802.11ax, and emerging 802.11be (Wi-Fi 7).
Analyze multi-antenna & multi-carrier transmission methods.
Optimize Wi-Fi bandwidth, security, and power management.
Implement Wi-Fi roaming, beamforming, and interference mitigation.
Wireless Communication
Wireless Digital Communications, Multi Carrier and Multi-Antenna System
Duration: 35 Hours (5 Days)
Level: Intermediate to Advanced
Course Overview
Wireless digital communication is the backbone of modern telecommunications, enabling high-speed data transfer over long distances with minimal interference. This course provides a comprehensive understanding of wireless digital communications, multi-carrier transmission, and multi-antenna systems.
Participants will learn to analyze and implement digital modulation techniques, including high-order modulation (256-QAM, 1024-QAM) used in 4G, 5G, and Wi-Fi. The course also covers OFDM transceiver design, MIMO (Multiple-Input, Multiple-Output) techniques, and OFDMA for enhanced wireless performance.
Additionally, AI, deep learning, and digital signal processing (DSP) applications in wireless networks will be explored.
Who Should Attend?
Wireless Engineers – Developing and optimizing wireless networks.
Telecommunications Specialists – Enhancing 4G, 5G, and Wi-Fi performance.
RF System Engineers – Implementing multi-antenna systems (MIMO).
Network Engineers – Managing wireless protocols and resource allocation.
DSP & Signal Processing Engineers – Working with wireless modulation and coding.
AI/ML Researchers in Wireless Systems – Exploring AI-driven wireless optimization.
Why Choose This Course?
Covers wireless modulation, OFDM, MIMO, error control, and AI-driven wireless systems.
Hands-on training with MATLAB, Python, GNU Radio, and SDR hardware.
Learn 5G, AI-driven spectrum sensing, and future trends in wireless.
Learning Outcomes
By the end of this course, participants will:
Choose the best modulation and coding scheme for various wireless applications.
Analyze error performance of different digital modulation techniques.
Design receiver architectures for optimized wireless communication.
Understand broadband wireless system components and their interactions.
Develop and optimize OFDM transceiver structures for efficient data transmission.
Implement MIMO and OFDMA to enhance wireless performance.
Apply AI and deep learning for wireless system optimization and channel estimation.
Pre-requisites
Basic knowledge of wireless communications and networking.
Familiarity with digital signal processing (DSP) concepts.
Lab Setup
Development Tools:
MATLAB, Python (NumPy, SciPy), GNU Radio, Wireshark
Hardware Requirements:
Software-defined radios (SDRs) – USRP, RTL-SDR, BladeRF
Testing & Debugging:
Open-source simulation tools for OFDM & MIMO (e.g., LTE-Sim, 5G-LENA)
MATLAB scripts for channel modeling, OFDM signal generation, and error performance analysis
