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FAQ
Q: What is a phased array antenna?
A phased array antenna is an advanced antenna system that uses multiple radiating elements with electronically controlled phase shifts to steer the beam direction without mechanical movement.
Q: How does a phased array antenna differ from a traditional antenna?
- Traditional antennas rely on
mechanical steering(e.g., rotating dishes). - Phased arrays use
electronic beam steering, enabling faster response, multi-beam operation, and no moving parts.
Q: What are the main components of a phased array antenna?
- Radiating elements(patches, dipoles, or slots)
Phase shifters(analog or digital) Amplifiers & LNAs(for active arrays) Beamforming controller(FPGA/DSP-based) Power distribution & cooling systems
Q: What is beamforming, and how does it work?
Beamforming is the process of combining signals from multiple antenna elements to create a focused beam in a desired direction by adjusting phase and amplitude.
Q: What are the key performance metrics for phased arrays?
- Beam steering speed(µs to ms range)
Scan angle(±45° to ±60° typical) Gain & directivity Side lobe levels(SLL) Power efficiency & heat dissipation
Q: What is the difference between analog and digital beamforming?
- Analog beamforminguses phase shifters and combiners in the RF domain.
Digital beamformingprocesses signals digitally at each element, offering more flexibility but higher complexity.
Q: What are hybrid beamforming architectures?
A combination of analog and digital beamforming, often used in
Q: How do you mitigate grating lobes in phased arrays?
- Element spacing ≤ λ/2(for broadside beams)
Non-uniform array layouts(e.g., random or tapered spacing) Advanced beamforming algorithms
Q: What are the challenges in designing high-frequency phased arrays (mmWave/THz)?
- Higher path loss→ Requires high gain & beamforming
Thermal management(due to high-power amplifiers) Precision manufacturing(small wavelengths demand tight tolerances)
Q: How do you calibrate a phased array antenna?
- Near-field/far-field testing
Built-in self-test (BIST) circuits Phase & amplitude compensation algorithms
Q: Why are phased arrays preferred for satellite communications (SATCOM)?
- Rapid beam switchingfor LEO/MEO satellite tracking
Multi-beam operationfor high-throughput links Low-profile designsfor airborne/mobile terminals
Q: How do phased arrays enhance 5G networks?
- Massive MIMOfor increased capacity
Dynamic beam trackingfor mobile users mmWave coverage extension
Q: Can phased arrays be used for radar systems?
Yes! They are widely used in:
AESA (Active Electronically Scanned Array) radars(military/aviation) Automotive radar(self-driving cars) Weather & surveillance radars
Q: Are phased arrays suitable for UAVs/drones?
Absolutely! Benefits include:
Lightweight & low-power designs High-speed beam steeringfor real-time data links Resistance to vibration & shock
Q: What role do phased arrays play in maritime communications?
- Stable satellite linksfor ships in rough seas (no mechanical tracking needed)
Anti-jamming capabilitiesfor secure military comms Multi-band operation(e.g., Inmarsat, Iridium, VSAT)
Q: What customization options do you offer?
- Frequency bands(L, S, C, Ku, Ka, mmWave)
Array size & element count(4×4 to 1000+ elements) Packaging(conformal, flat-panel, ruggedized) Integrated RF components(up/down converters, filters)
Q: What is the typical lead time for a custom phased array?
- Off-the-shelf models: 4-8 weeks
Fully custom designs: 3-6 months (depending on complexity)
Q: Do you provide simulation & prototyping services?
Yes! We offer:
EM simulation(HFSS, CST) Prototype testing(anechoic chamber, OTA measurements) Regulatory compliance support(FCC, CE, MIL-STD)
Q: What after-sales support do you provide?
- On-site installation & training
Firmware/software updates Repair & recalibration services
Q: How do I request a quote or demo?
Contact our sales team at
