Transmission line probes are a special type of passive probe designed for use at very high frequencies. They replace the high impedance probe cable found in a traditional passive probe with a precision transmission line, with a characteristic impedance that matches the oscilloscope input (50 Ohm). This greatly reduces the input capacitance to a fraction of a picofarad, minimizing the loading of high frequency signals. A matching network at the tip increases the DC input resistance. While they have lower DC input resistance than a traditional passive probe (usually 500 Ohm) to 1kOhm), the input impedance of these probes remains nearly constant over their entire frequency range. A traditional /10 passive probe will have a 10 MOhm) input impedance at DC, however this impedance drops rapidly with frequency, passing below the input impedance of a transmission line probe at less than 100 MHz.

• Ultra-Low Swap: Saving launch and operational costs
• Wide FOV (Field of View): 6.3° x 4.3° / 54 x 36 km2 from a 500km orbit

• Low output capacitance 
• High bandwidth up to 30kHz 
• High resolution I-V curve simulates static and dynamic conditions 
• Designed for high speed Maximum Power Point Tracking (MPPT) 
• Can be integrated into a multi-channel system for higher power testing 
• Low voltage, high bandwidth version for DC Power Optimizers 
• EN50530 support

• Full configuration and performance testing according to Y.1564
• Complete validation of Ethernet service-level agreements (SLAs) in a single test
• Multiple protocols supported per UNI (Ethernet, Customer and Service VLANs, MPLS, IPv4, IPv6, and UDP)
• Define Per-UNI or per-CoS bandwidth profiles, and specify CoS-to-DSCP mapping
• Support for different network topologies and traffic flow directions

• Modular 6.5 digit DMMs for the EX1200 mainframes 
• Tightly integrated into mainframes, allowing high-speed, synchronized scanning measurements without the need for external cabling. 
• Input can be routed directly to the DMM or through an internal analog bus on the backplane. 
• Super fast scanning with no processor intervention required 
• Scanning configuration can be saved in the DMM’s non-volatile memory allowing quick recall of saved states 
• Integrating ADC for with adjustable integration time depending on the level of accuracy required. 
• “True RMS” AC readings 
• Frequency and temperature measurements

These sensors detect the presence or movement of a magnet, enabling precise position or proximity monitoring. Available in Reed or Hall effect versions, they are used in medical, industrial, and consumer devices.

• The RL36120 is characterized as a Large Aimed Bright Field ring light. 
• Precisely aimed LEDs provide a level of lighting control not found in traditional illuminators. 
• A range of standoffs and fields of view may be specified at the time of order. 
• The ring light is available in a wide range of wavelengths from UV to IR, including a 3 channel RGB version. Diffuser and polarizer options are also available. 
• The large inner diameter of the ring light can accommodate lenses up to 55mm in diameter. 
• The light can also be ordered with an optional mounting ring.

• SPA available from 70KHz to 20/40/70/110/125/145 and 220GHz. Also available for banded configuration to 1.1THz.
• Dual SPA mode available: suitable for Mixers/Amplifier/ Harmonics /Spurious testing.
• SPA available on all ports. User can define which port to use as SPA port.
• Several detection types available in classical mode: Peak, minimum, RMS, Mean.
• Various math functions can be applied on SPA mode like Min hold/max hold/ user defined equations.
• Sources and receivers can be independently configured. Can be used as Tracking Generator.
• For units that have a dual source, a dual drive option is available. Support for external source control also possible.
• Phase synchronization for units with Dual source available. This feature allows users to control and configure the phase between the two sources.
• Source and receiver attenuator available with VNA can be activated in SPA mode. Recommendation to use option 62 (with attenuator on receiver side) for measuring the spectrum content of high-power devices.
• Software option: easy to install and upgrade existing user equipment.

The latching / bi-stable (1 Form E) reed switch is a magnetically operated switch designed for ultra-low power applications, particularly in battery-powered and energy-sensitive systems. Unlike traditional reed switches, this bistable variant maintains its contact state, either open or closed, without continuous power, thanks to its dual-magnet latching mechanism.

The switch operates by using two permanent magnets: one partially magnetized to bring the contacts near each other, and a second magnet that controls the contact state by reversing its magnetic field. This design allows the switch to remain in either the normally open (N.O.) or normally closed (N.C.) state until actively changed, making it ideal for applications requiring stable switching with minimal energy consumption.