| 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-JCFS360-2, is engineered for high-precision test assemblies and broadband measurement systems using the CFS360 ultra-low-loss, phase-stable coaxial cable. Operating from DC to 40 GHz with 50 Ω impedance, VSWR ≤ 1.17, and insertion loss ≤ 0.06 √f dB, it provides exceptional signal stability and repeatable impedance control across microwave and millimeter-wave frequencies. Explore related models in the 2.92 mm connector family.
The 2.92-JCFS360-2 connector ensures low reflection, tight impedance matching, and stable S-parameters throughout its operational range. Designed for calibration kits and VNA testing systems, it delivers consistent return-loss behavior and excellent electrical precision under demanding laboratory conditions.
Manufactured from passivated stainless steel with a gold-plated beryllium-copper contact, the 2.92-JCFS360-2 offers durability, corrosion resistance, and low contact resistance across frequent mating cycles. Its precisely machined interface supports repeatable broadband measurements and long-term phase stability. Discover more high-performance options in our RF connectors catalog.
The solder-mount termination securely bonds the outer conductor and safeguards the dielectric from mechanical deformation, ensuring low insertion loss and consistent impedance during operation. For comparable designs supporting solder or crimp terminations, see cable-mount connectors.
When integrated with the CFS360 ultra-low-loss, phase-stable coaxial cable, the 2.92-JCFS360-2 connector delivers exceptional signal integrity, repeatable impedance matching, and low attenuation—ideal for precision calibration assemblies, VNA test systems, and high-frequency measurement environments.