Services/Capabilities

Training and Skill Development Programmes: https://drive.google.com/file/d/1hCBSZZDZQw6yxU8KUdgIh1RhrgO3g4yr/view?usp=sharing

Training: 

SmaSys offers specialized training programs designed to build technical expertise and practical skills in the fields of radar systems, RF & Microwave passive and active circuits, antenna design, and signal processing. Our courses are developed and delivered by industry veterans and subject matter experts with hands-on experience in defense, aerospace, and communications industries.

Whether you're an engineer, researcher, or technical manager, our training equips you with the knowledge to solve complex challenges and stay ahead in rapidly evolving technology landscapes.

Radar Systems Training

Gain a comprehensive understanding of radar technologies — from basic principles to advanced system design and implementation.

Courses include:

• Fundamentals of Radar Engineering

• Modern Radar Architectures (CW, FMCW, SAR, AESA, MIMO)

• Target Detection & Tracking Algorithms

• Radar Signal Simulation and Processing

• Radar System Integration and Testing

• Electronic Warfare and Countermeasure Techniques

Antenna and Microwave Training

Learn how to design, simulate, and evaluate high-performance antennas for a wide range of applications.

Courses Include:

• Antenna Theory and Fundamentals (radiation, impedance, polarization)

• Modern Electronic Warfare (EW) Antennas

• Beamforming for 5G system Design & Simulation 

• MM Wave Engineering Concepts in Weaponary Warfare Systems

• EMP Protection Methodologies for Electronics Systems 

• Design of Broadband EW Antennas and Radomes 

• RF and Microwave Passive and Active Circuits

• Microwave Measurement Laboratory

• EMI/EMC Design

• Antenna Measurement Techniques

• Platform Integration and Environmental Considerations

Signal Processing for Radar and Communications

Master signal processing techniques essential for interpreting and manipulating radar and RF signals in real time.

Courses include:

• Digital Signal Processing (DSP) Basics

• Time-Frequency Analysis and Filtering

• Adaptive Beamforming & STAP

• Detection & Estimation Theory

• Machine Learning in Signal Processing

• Real-Time Implementation using MATLAB, Python, and FPGA

Training Formats

• On-Site & In-House Training: Customized for your team’s needs at your facility.

• Virtual Instructor-Led Courses: Flexible and interactive sessions via secure platforms.

• Workshops & Bootcamps: Intensive, application-focused training for rapid skill-building.

• Certifications & Continuing Education: Trackable and industry-relevant credentials.

Who Should Attend

• RF & Microwave Engineers

• Radar and EW System Designers

• Signal Processing Professionals

• Defense Technologists

• Graduate Students and Researchers

• Technical Managers and Project Leads

Why Train with Us

• Expert Instructors: Learn from practitioners with real-world system development experience.

• Hands-On Learning: Emphasis on simulation, measurement, and live demos.

• Tailored Content: Adaptable curriculum to match your application domain and technical level.

• Industry-Ready Skills: Focus on tools, techniques, and challenges faced in operational environments.

Technical Consultancies: 

At the forefront of advanced electromagnetic and signal technologies, our technical consultancy delivers expert-driven solutions in radar systems, antenna design, and signal processing. With deep domain knowledge and cross-disciplinary expertise, we support clients across defense, aerospace, telecommunications, automotive, and scientific research sectors. 

Radar Systems

Our radar consultancy services cover the entire lifecycle of radar system development — from concept and feasibility studies to system-level design, simulation, testing, and performance optimization.

Expertise includes:

• Radar system architecture (CW, FMCW, pulse-Doppler, SAR, MIMO)

• Detection, tracking, and classification algorithms

• Radar cross-section (RCS) analysis and signature modeling

• Clutter modeling and mitigation

• Embedded radar firmware development

• Performance assessment under EW and LPI/LPD constraints

RF & Microwave Circuits, Antenna Design & Integration

 We offer specialized expertise in designing, simulating, and integrating microwave active and passive circuits and antennas for both commercial and defense applications. Our approach ensures optimal performance in challenging environments, including conformal and embedded configurations.

 Expertise includes:

• Development of Microwave Passive and Active circuits

• Development of wideband, compact, 3D & 2D (Planar) antennas

• Development of reconfigurable/smart antennas

• Development of antenna arrays and power combining networks

• Development of RF & Microwave passive and active components

• Integration with platforms (airborne, naval, ground-based)

• Antenna far-field measurements and validation

• Electromagnetic (EM) simulation (HFSS, CST, and ADS)

Signal Processing Solutions

Our consultants provide advanced signal processing strategies tailored to extract actionable intelligence from complex and noisy environments. 

Expertise includes:

• Time-frequency analysis and wavelet transforms

• Adaptive filtering, beamforming, and STAP

• Target detection and parameter estimation (range, Doppler, angle)

• Machine learning for classification and anomaly detection

• Digital receiver and FPGA/SoC-based real-time implementation

Why Choose Our Consultancy

Multidisciplinary Expertise: Bridging theory and practical deployment in radar, RF, DSP, and machine learning.
Cutting-Edge Tools: Proficiency in industry-standard simulation and development platforms.
Customized Solutions: We tailor strategies based on your application, budget, and performance goals.

Whether you're developing a next-generation radar system, optimizing your antenna arrays, or refining signal processing algorithms, our consultancy provides the critical insights and hands-on support to accelerate innovation and reduce risk.

Research/Innovation:

• RFID and Smart Glove: SMART GLOVES have been extensively used in various domains such as medical and industrial applications since they are lightweight and comfortable to wear. Among others, Radio Frequency Identification (RFID) technology integrated into protective gloves is suitable for helping workers during their activities, minimizing human effort and accident risk. RFID systems are extensively used in various applications such as access control, electronic toll collection, waste management, tracking, IoT-based personal healthcare, item-level tagging, security, etc.

• Reconfigurable Active Antennas, Wireless Power Transfer, and Energy Harvesting: Integrating passive antennas with active devices is a growing area of research in various applications such as beam steering, quasi-optical power combining, and beam switching. Millimeter-wave frequencies have several fundamental issues, such as higher transmission line loss, lower antenna efficiency, and limited source capacity. Power combiners become lossy at Millimeter-wave frequencies. Reconfigurable active antennas can be a good candidate for millimeter frequencies in quasi-optical power combining, wireless charging, broadcasting, secure communications, etc. 

• Antennas for Automotive and Body Area Network: In the last decades, the number of mobile and wireless applications has rapidly increased, and some specific applications, such as cellular communications, have experienced a significant evolution. For example, the demand for wideband cellular antennas for Long Term Evolution (LTE) and 5G communication systems is continuously increasing in smartphones and vehicular applications. In particular, intending to make a vehicle as “smart” and autonomous as possible, in the automotive industry, the number of wireless services is significantly increasing, which consequently leads to a higher number of embedded radiating elements. Even though the size of a vehicle is expected to allow for easy integration of a multitude of antennas, specific integration constraints are coming from aesthetic, mechanical, and electromagnetic domains, which must be taken into account during the antenna and system design. It is well known that one of the best positions for antennas is above the vehicle roof since the radiating elements are not affected by surrounding mechanical components, and better radiation toward the cellular base stations is guaranteed. Antennas are typically integrated under plastic covers, named shark fins. However, the increase of wireless functionalities in the automotive industry results in complex electronic systems, networks, and architectures [1]. Thus, the integration of antennas is challenging in those cases where multiple antennas are present because antenna compactness and isolation requirements are complicated to fulfill. The size of the antenna is limited by the available volume under the cover and by the presence of other antennas placed nearby. Typical car roof modules include antennas for cellular communications, Vehicle to Everything (V2X), Bluetooth, Wireless Local Area Network (WLAN), Global Navigation Satellite Services (GNSS), and satellite radio services such as Satellite Digital Audio Radio Systems (SDARS). Nevertheless, multiple antennas are used to improve the throughput of LTE or 5G cellular systems by implementing Multiple Input Multiple Output (MIMO) wireless technology.

• SSPP Transmission Lines and Leaky-Wave Antennas: Surface plasmon polaritons (SPPs) are highly localized surface waves that exist on the metal-dielectric interface at optical frequencies [1]. The SPPs offer excellent performance at optical frequencies but cannot be generated naturally at microwave frequencies because metal behaves as a perfect electric conductor (PEC) at microwave frequencies. In [2] and [3], SPP structures called mimic structures have been proposed at microwave frequencies. These designed structures are known as spoof surface plasmon polaritons (SSPPs). Recently, many SSPP-based structures have been used to design passive components such as filters, antennas, and splitters, but leaky-wave antennas (LWAs) based on SSPP have gained a lot of attention. The leaky-wave antenna is a type of traveling wave antenna having outstanding properties. These leaky-wave antenna structures have high directivity and wide frequency scanning and require a simple feeding network.

• Reconfigurable Antennas: Reconfigurable antennas are a class of antennas whose operating characteristics can be dynamically altered to adapt to changing requirements or environments. These modifications can involve frequency, radiation pattern, polarization, or even impedance, and they're achieved through various physical and electronic reconfiguration mechanisms.