RF Antennas

Part Number	Description / PDF	Quantity
PRO-OS-297 ProAnt	RF ANT 434/892MHZ CAB CHAS 1.5M	132
PRO-OB-471 ProAnt	RF ANT 868MHZ/915MHZ STAMPED MET	2639
PRO-EX-332 ProAnt	RF ANT 2.4GHZ WHIP TILT SMA MALE	3
PRO-EX-296 ProAnt	RF ANT 2.4GHZ WHIP STR CAB PAN	302
PRO-IS-587 ProAnt	INSIDE 2400 TRIANGULAR 10CM MHF4	128
PRO-OS-291 ProAnt	RF ANT 434MHZ/892MHZ CAB CHAS 3M	132
PRO-EX-286 ProAnt	RF ANT 2.4GHZ/5.5GHZ WHIP TILT	359
PRO-OS-289 ProAnt	RF ANT 434MHZ/892MHZ FME CHAS MT	117
PRO-EX-388 ProAnt	RF ANT 892MHZ/1.85GHZ SMA 57MM	111
PRO-OB-430 ProAnt	RF ANT 1.575GHZ/1.602GHZ STAMPED	2932
PRO-IS-432 ProAnt	RF ANT 2.4/5.5GHZ PCB TRACE CAB	982
PRO-EX-285 ProAnt	RF ANT 2.4GHZ/5.5GHZ WHIP TILT	43
PRO-IS-589 ProAnt	INSIDE GSM/NB-IOT ADHESIVE MHF4	491
PRO-OB-440 ProAnt	RF ANT 2.4GHZ STAMPED MET SLD	62801

RF Antennas

1. Overview

RF/IF (Radio Frequency/Intermediate Frequency) antennas and RFID (Radio Frequency Identification) antennas are critical components in wireless communication systems. RF/IF antennas transmit and receive radio frequency signals, while RFID antennas enable contactless data exchange between tags and readers. These technologies underpin modern applications such as IoT, 5G networks, logistics tracking, and smart devices, driving efficiency and connectivity across industries.

2. Major Types and Functional Classification

Type	Functional Characteristics	Application Examples
Dipole Antennas	Balanced radiation pattern, omnidirectional coverage	Wi-Fi routers, radio broadcasting
Microstrip Patch Antennas	Compact, planar design, directional beam	Mobile devices, satellite communication
Loop Antennas	High sensitivity for near-field applications	Retail RFID payment systems
Fractal Antennas	Multiband operation with miniaturized geometry	Military communication, wearable devices
Far-Field RFID Antennas	Long-range UHF operation (>860 MHz)	Warehouse inventory management
Near-Field RFID Antennas	Short-range HF operation (13.56 MHz)	Contactless payment, access control

3. Structure and Components

A typical RF/IF antenna consists of:

Conductive elements (copper, aluminum) for signal radiation
Dielectric substrates (FR4, Rogers materials) for impedance control
Feed lines (coaxial cables, microstrip lines) for signal transmission
Enclosures for environmental protection

RFID antennas integrate additional components like impedance matching circuits and chip interfaces, with designs optimized for magnetic or electric field coupling.

4. Key Technical Specifications

Parameter	Description	Importance
Frequency Range	Operational bandwidth (e.g., 860 960 MHz for UHF RFID)	Determines application compatibility
Gain (dBi)	Signal directionality and strength (2 8 dBi typical)	Affects transmission distance and efficiency
Impedance	Matching standard (usually 50 )	Minimizes signal reflection
VSWR	Voltage Standing Wave Ratio (<2:1 preferred)	Indicates power transfer efficiency
Polarization	Linear/circular orientation	Impacts signal stability in dynamic environments

5. Application Fields

Telecommunications: 5G base stations, DAS (Distributed Antenna Systems)
Healthcare: MRI RF coils, patient monitoring systems
Transportation: ETC (Electronic Toll Collection), vehicle-to-everything (V2X) communication
Retail: Smart shelves, inventory tracking with RFID
Industrial: Asset management, drone communication

6. Leading Manufacturers and Products

Manufacturer	Representative Product	Features
Avnet	RFID UHF Reader Antenna A1001	Linear polarization, 902 928 MHz, 6 dBi gain
Alien Technology	ALN-9652 IMPINJ R4P	Passive UHF RFID, 860 960 MHz
Pulse Electronics	LF RFID Antenna PLX17R	125 kHz, embedded in access control systems
Kathrein	RF Dipole Antenna 80010133	2.3 3.8 GHz for 5G small cells

7. Selection Recommendations

Key factors to consider:

Frequency alignment with system requirements
Environmental durability (temperature, moisture, vibration)
Size constraints for PCB or mechanical integration
Cost vs. performance trade-offs for mass deployment
Regulatory compliance (FCC, ETSI standards)

For RFID systems, prioritize read range and tag compatibility; for high-frequency RF applications, emphasize VSWR and phase stability.

8. Industry Trends

Emerging trends include:

Development of mmWave (24 100 GHz) antennas for 5G/6G
Miniaturization via metamaterials and 3D printing
AI-optimized beamforming antennas for IoT networks
Conductive ink-based flexible RFID tags for disposable applications
Integration of energy harvesting capabilities

The global RFID antenna market is projected to grow at 12.3% CAGR through 2027, driven by smart city initiatives and supply chain digitization.