New R&S NGA100 series power supplies are available in four models, providing a choice of single and dual outputs with up to 35 V/6 A per output, or 100 V/2 A per output. Single-output models supply up to 40 W, dual output models up to 80 W power. The dual model outputs can be combined to provide up to 200 V or 12 A.
Rohde & Schwarz has implemented a linear design throughout the output circuits of the R&S NGA100 which significantly improves performance compared to the switched-mode circuits frequently found in basic power supplies. The resulting higher accuracy means engineers can be confident of supplying exactly the right power level without any need for an additional multi-meter. The standard level of read-back resolution, 1 mV/100 µA, is enhanced for currents under 200 mA to a resolution of 1 µA, ideal to test low current levels typical for IoT applications in standby and sleep mode. The R&S NGA100 also has the necessary dynamic range for the power and current spikes from the same devices when switched to active mode.
While many basic power supplies only output maximum power within a very limited voltage/amperage range, the R&S FlexPower technology provides maximum power for a wide range of combinations, so a single instrument can support many different applications. No matter which application, users benefit from the clear screen, intuitive user interface, and features like instantaneous statistical functions for maximum and minimum values for power, voltage and current, displayed directly on the screen.
Other features of the R&S NGA100 not commonly found in a basic power supply include logging voltage and current values for analysis, with up to 10 samples per second. For data export and remote control, Ethernet and USB are supported as standard, with optional WLAN and an external trigger with Digital I/O. Users can generate sequences of voltage/current settings at intervals down to 10 msec. The supplied power is not only low-distortion and low-noise, but thanks to the instrument’s remote sensing function, cable losses can even be compensated for. The correct level is at the input to the device under test, not at the output of the power supply.