As the professional manufacturer, we would like to provide you R&S NRP33S Three-path Diode Power Sensors. The R&S®NRPxxSN-V TVAC-compliant power sensor is designed for satellite communications applications in a frequency range up to 67 GHz.
Models | R&S®NRP33S |
Frequency range | 10 MHz - 33 GHz |
Level range | -70 dBm - +23 dBm |
LAN interface | |
Connector type | 3.5 mm (m) |
Fast and accurate power measurements for CW and modulated signals
100,000 readings/s
Control and monitoring via LAN and USB
Sensors for high-power applications
Flexible operation with R&S®NRX base unit
The R&S®NRPxxS/SN power sensors use three separate diode paths, each operated in the optimum detector range. As a result, the average power can be determined with high accuracy independent of the modulation type. Measurement results are hardly affected by interfering signals or harmonics. The R&S®NRPxxS/SN power sensors therefore behave in a way similar to thermal power sensors but offer significantly higher speed. They provide up to 93 dB dynamic range with an excellent lower measurement limit of –70 dBm.
Ideal solution for many applications
As the professional manufacturer, we would like to provide you R&S NRP33S Three-path Diode Power Sensors. Three-path diode power sensors are suitable for numerous applications, since they support continuous average, burst average, timeslot average, gate average and trace measurements. Featuring outstanding performance and unprecedented measurement speed and accuracy, the sensors can be used to perform precise average power measurements on wireless signals such as GSM and 3GPP as well as on higher bandwidth signals such as LTE, LTE-Advanced or 5G.
Improved thre-path concept
The R&S®NRPxxS(N) power sensors use three separate diode paths, each operated in the optimum detector range. The average power can be determined with high accuracy irrespective of the modulation type. Measurement results are hardly affected by interfering signals or harmonics. The R&S®NRPxxS(N) power sensors therefore behave similar to thermal power sensors but offer significantly higher speed and up to 93 dB dynamic range.
Even at low levels down to -70 dBm
To increase measurement accuracy at low levels, it is necessary to average multiple measured values. While averaging reduces the noise component, it also slows down the measurement. The R&S®NRPxxS(N) power sensors have therefore been designed with an extremely low measurement noise in mind.
The R&S®NRPxxS(N) power sensors can perform measurements down to a lower limit of –70 dBm with the highest speed and accuracy currently available on the market.
Unlimited time measurement with up to 100.000 measurements/s
In fast continuous average mode, the R&S®NRPxxS(N) power sensors can perform up to 100,000 triggered measurements/s with a minimum trigger repetition time of 100 µs without losing any measurement. This measurement speed is achieved by using the buffered mode. In buffered mode, all measured data is collected inside the sensor and transmitted in one block to the sensor's host. The R&S®NRPxxS(N) sensors perform the new fast mode without time limitation!
Perform power measurements up to 30 W
The R&S®NRP18S-10, R&S®NRP18S-20 and R&S®NRP18S-25 high-power three-path diode power sensors consist of an R&S®NRP18S and a 10/20/25 dB upstream attenuator. They are able to perform power measurements up to 2 W, 15 W and 30 W. When used with the attenuator, mismatch errors between the sensor and attenuator are automatically corrected. The S-parameters for the attenuator are determined and stored in the sensor during production.
Specially designed for use in thermal vacuum (TVAC) chambers
The R&S®NRPxxSN-V TVAC-compliant power sensor is designed for satellite communications applications in a frequency range up to 67 GHz. All components are baked in a vacuum chamber during the production process, so outgassing is reduced to a minimum. Thanks to their LAN capability, the power sensors can be easily controlled and monitored from outside the chamber while the venting holes in the housing ensure pressure equalization.