| Quantity | Price |
| 1 - 99 | 23,00 $ |
| 100 - 199 | 22,54 $ |
| 200 - 499 | 22,31 $ |
* All Prices are in US Dollars and do not include duties
Key Specifications
Frequency Max
Connector Series
Connector Gender
Body Style
VSWR Max
Termination Type
Interface Type
Attachment Method
Mount Method
Description
The 2.92 mm male straight cable-mount RF connector, model 2.92-JCFT390-1, is engineered for low-loss and phase-stable broadband performance with the CFT390 low-loss, phase-stable coaxial cable. Supporting DC to 40 GHz operation with a 50 Ω impedance, VSWR ≤ 1.17, and insertion loss ≤ 0.06 √f dB, it ensures outstanding return-loss control and high repeatability for microwave instrumentation and signal distribution systems. Discover other precision-engineered interfaces in the 2.92 mm connector family.
The 2.92-JCFT390-1 connector provides stable impedance characteristics and minimal reflection across broadband frequencies. Its precision interface guarantees phase stability and repeatable insertion loss, making it ideal for VNA calibration assemblies and high-frequency testing platforms where reliability and accuracy are essential.
Machined from passivated stainless steel and fitted with a gold-plated beryllium-copper center contact, the 2.92-JCFT390-1 offers exceptional wear resistance, mechanical strength, and low contact resistance. Its tight interface tolerances ensure stable S-parameter behavior during repetitive mating cycles. For similar precision-grade interconnects, visit RF connectors.
The solder-mount termination provides robust strain relief and mechanical support for long-term performance. The internal dielectric centering preserves impedance uniformity under thermal cycling and vibration stress. Explore related termination geometries within cable-mount connectors.
When paired with the CFT390 low-loss, phase-stable coaxial cable, the 2.92-JCFT390-1 connector delivers superior impedance control, minimal attenuation, and excellent broadband repeatability—making it ideal for microwave calibration fixtures, RF instrumentation, and high-stability test environments.