Cable Assemblies
Amphenol’s cable assemblies include simple point-to-point cables, custom high-power and high-speed data cable assemblies and complex multi-branch harness assembly for large systems across a broad range of end markets. Our cable assemblies include the latest industry innovations in radio frequency (RF), fiber optics, high-power requirements and high-speed data transfer for the newest systems and applications. In addition, our broad portfolio of cable connectors and accessories can be used in our cable assemblies to provide a complete solution.
View our businesses providing Cable Assemblies solutions.
PTSRB-047
The PhaseTrack®-047 is a Semi-Rigid phase-stable coax assembly featuring a proprietary fluorocarbon dielectric, TF4®, eliminating the PTFE change phase occurring around 19 ºC. The PhaseTrack Semi-Rigid cable assemblies are perfect for in-the-box or extreme environment applications where stable phase over temperature is necessary.
PTSRB-086
The PhaseTrack®-86 is a Semi-Rigid phase-stable coax assembly featuring a proprietary fluorocarbon dielectric, TF4®, eliminating the PTFE change phase occurring around 19 ºC. The PhaseTrack Semi-Rigid cable assemblies are perfect for in-the-box or extreme environment applications where stable phase over temperature is necessary.
PTSRB-141
The PhaseTrack®141 is a Semi-Rigid phase-stable coax assembly featuring a proprietary fluorocarbon dielectric, TF4®, eliminating the PTFE change phase occurring around 19 ºC. The PhaseTrack Semi-Rigid cable assemblies are perfect for in-the-box or extreme environment applications where stable phase over temperature is necessary.
pulseOne Cable Assemblies
The pulseOne over-molded plug and receptacle cable assemblies are designed to meet the growing need for simple, standard, readily available medical-grade cable assemblies. Its ergonomic shape, environmental sealing features, and affordability make pulseOne an ideal choice for diagnostic, therapeutic, and surgical devices, as well as human-worn applications.
PwrBlade® Cable Assembly
The PwrBlade® cable connectors are designed to mate to PwrBlade® R/A or vertical board-mounted headers. By expanding beyond BTB applications, designers can now connect power supplies and power distribution sub-assemblies in a wider range of applications. The combination of cable connection capability with Amphenol's proven PwrBlade BTB system provides a universal power distribution connector.
PwrBlade® ULTRA HD+ Cable Assembly
HIGH-POWER CABLE-TO-BOARD CONNECTOR SYSTEM
Amphenol's PwrBlade® ULTRA HD+ Cable-to-Board serves as a high-power I/O cable configuration in a low-profile design. The connector features an enhanced contact design capable of providing up to 84A per contact (per 4 adjacent contacts) and high-density signal options with up to 6 signal pins per column.
Pwr TwinBlade® Cable Assemblies
The Pwr TwinBlade® cable system is designed to support applications that demand the supply of high power. The Pwr TwinBlade® connectors employ a proven contact system in a touch-proof design that is capable of supporting currents of up to 100A per contact. The new sensing contacts can be used to eliminate the potential for damage from hot-plug conditions.
QSFP Cable Assemblies
Amphenol's QSFP copper cable assemblies are designed to meet data center, networking and high-performance computing application needs for high density cabling interconnect systems capable of data rates from 10G/Lane to 112G/Lane transmission rates.
QSFP DD Cable Assemblies
200G / 400G / 800G SOLUTIONS
Amphenol's QSFP DD (Double Density) copper cable assemblies double the number of channels from 4 to 8 lanes when compared to the existing QSFP cabling systems, enabling more bandwidth within the same mechanical envelope.
QSFP DD OverPass™ Assemblies
56G AND 112G DIRECT HIGH SPEED CONNECTION FROM CHIP SITE TO IO PORT
QSFP DD OverPass™ products remove high speed signaling from the PCB and create an eight channel direct lower loss interconnection between the ASIC site and the external QSFP DD IO port by overpassing the PCB. This helps to enable 56G and 112G hardware system designs and a technology for future 224G systems.