| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Panasonic |
RELAY RF 3GHZ SPDT 500MA 3V |
0 |
|
 |
Panasonic |
RELAY RF 1 FORM C 9V |
25 |
|
 |
Panasonic |
RELAY RF DPDT 1A 3V |
0 |
|
 |
Panasonic |
RELAY RF 3GHZ SPDT 500MA 9V |
0 |
|
 |
Omron Electronics Components |
RELAY RF DPDT 1A 5V |
4494 |
|
 |
Panasonic |
ARS RELAY 1 FORM C 3V |
0 |
|
 |
Panasonic |
RELAY RF 3GHZ SPDT 500MA 9V |
0 |
|
 |
Panasonic |
RELAY RF SPDT 500MA 12V |
0 |
|
 |
Panasonic |
RELAY RF SPDT 500MA 3V |
0 |
|
 |
Omron Electronics Components |
RELAY RF DPDT 1A 4.5V |
960 |
|
 |
Panasonic |
ARS RELAY 1 FORM C 9V |
0 |
|
 |
TE Connectivity Potter & Brumfield Relays |
RELAY RF SPDT 2A 6V |
0 |
|
 |
Panasonic |
RELAY RF SPDT 500MA 12V |
1628 |
|
 |
Panasonic |
RELAY RF 3GHZ SPDT 500MA 4.5V |
0 |
|
 |
Panasonic |
RELAY RF 3GHZ SPDT 500MA 12V |
0 |
|
 |
Coto Technology |
RELAY RF SPST 500MA 12V |
0 |
|
 |
Coto Technology |
RELAY RF SPST 500MA 12V |
0 |
|
 |
Panasonic |
RELAY RF 3GHZ SPDT 500MA 24V |
0 |
|
 |
Omron Electronics Components |
RELAY RF DPDT 1A 12V |
0 |
|
 |
Panasonic |
RELAY RF SPDT 500MA 12V |
101 |
|
High Frequency (RF) Relays are electromechanical or solid-state devices designed to switch high-frequency electrical signals (typically above 1 MHz) in radio frequency (RF) circuits. They enable reliable signal routing in communication systems, test equipment, and industrial applications. With the advancement of 5G, IoT, and wireless technologies, RF relays have become critical components for maintaining signal integrity in high-speed data transmission systems.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| Electromechanical RF Relays | Metal contacts with electromagnetic actuation, suitable for high power handling (up to 1 kW) | Telecom infrastructure, broadcast equipment |
| Solid-State RF Relays | Semiconductor-based switching with nanosecond response time | Automated test equipment (ATE), medical imaging |
| Coaxial Relays | Designed for coaxial cable systems with impedance matching (50/75 ) | Satellite communication systems |
| PCB Mount RF Relays | Surface-mount design for compact RF circuit integration | Portable test instruments, aerospace electronics |
Typical RF relay construction includes: - Enclosure: Hermetically sealed metal housing (aluminum/steel) for EMI shielding - Contact Materials: Beryllium copper alloy with gold plating for low contact resistance - Actuation Mechanism: Electromagnetic coil or MOSFET driver circuit - RF Path: Precision-machined transmission lines with ceramic insulation - Termination: SMA/N-type connectors or SMD pads for PCB integration
| Parameter | Typical Range | Importance |
|---|---|---|
| Frequency Range | DC-40 GHz (waveguide up to 110 GHz) | Determines application bandwidth |
| Power Handling | 1W-2kW (CW/Peak) | Prevents signal distortion/overheating |
| Insertion Loss | 0.1-2.5 dB | Minimizes signal attenuation |
| VSWR | 1.1:1-1.8:1 | Measures impedance matching quality |
| Switching Life | 10^6-10^8 operations | Dictates long-term reliability |
| Switching Speed | 5ms-100ns | Critical for test automation systems |
Major application sectors include: - Telecommunications: 5G base stations, microwave backhaul systems - Test & Measurement: RF spectrum analyzers, network analyzers - Medical: MRI systems, radiation therapy equipment - Industrial: Semiconductor manufacturing equipment - Aerospace: Radar systems, satellite payload switches
Case Study: In 5G massive MIMO systems, coaxial RF relays enable dynamic antenna array configuration with <0.5dB insertion loss at 3.5GHz.| Manufacturer | Representative Product | Key Features |
|---|---|---|
| TE Connectivity | KILOVAC EV200AA | 40kV isolation, space-grade reliability |
| OMRON | G5RL-U1-E-DC5 | Compact 5V PCB relay for IoT devices |
| Crydom | RF1A240D25 | 240VAC switching with 25A capacity |
| Pickering | 60-700 Series | LXI-controlled relay matrices for ATE |
Key selection criteria: - Match frequency requirements with relay's -3dB bandwidth - Verify voltage standing wave ratio (VSWR) for system impedance - Calculate power dissipation using P=I R formula - Consider mechanical/environmental factors (vibration, temperature) - Balance switching speed vs. contact wear in electromechanical types - Prioritize hermetic sealing for aerospace applications
Current development trends include: - Miniaturization: Chip-scale RF relays approaching 0.5mm - Frequency extension: 110GHz+ waveguide integrated designs - Smart integration: Relays with built-in position sensors - Material innovation: Graphene-coated contacts for reduced insertion loss - Increased focus on RoHS-compliant, lead-free manufacturing processes