A new type upward-looking airborne double-antenna microwave radiometer (ADAMR) system intended for detecting atmospheric cloud liquid water content (LWC) is developed in this paper. The frequency of this radiometer is 31.65 GHz. For the antenna elevation angle, one is 30°and the other is 90°. In order to detect the signals with low effective noise temperature (<10K) from the LWC, the noise coupling technique is used. Through injecting constant equal noise signal into the two antenna ports respectively, the technique can elevate the small input noise signal power to the detectable range of the square-law detector and thus realize the weak signal detection. Moreover, in order to eliminate the impacts of the system gain fluctuations and obtain a higher sensitivity, an auto-gain compensation method based on the analog-to-digital converter, microcontroller and host computer software techniques is also proposed. Compared with the traditional radiometers, the radiometer topology is greatly simplified and the gain fluctuations can be readily realtime compensated using the compensation method. The laboratory test results show that radiometric sensitivity is better than 0.2 K for 300ms integration time and the instrument is conforming to specifications. Finally, the flight observation experiment results are presented to prove that the designed instrument is able to detect small changes of noise signal in a wide effective range of noise temperature (10-350K) and is a powerful tool for LWC measurement.
[1]
R. Dicke.
The measurement of thermal radiation at microwave frequencies.
,
1946,
The Review of scientific instruments.
[2]
Robert J. Serafin,et al.
Applications of airborne remote sensing in atmospheric sciences research
,
1984
.
[3]
Wang Yanfei.
Retrieval of Cloud Liquid Water Content Distribution at Vertical Section for Microwave Radiometer Using 2D Tomography
,
2010
.
[4]
Lei Heng.
Measurement of Column Cloud Liquid Water Content by Airborne Upward-Looking Microwave Radiometer (I): Instrument and Its Calibration
,
2003
.
[5]
Richard K. Moore,et al.
Microwave Remote Sensing, Active and Passive
,
1982
.
[6]
G. Poe,et al.
Sensitivity of the Total Power Radiometer with Periodic Absolute Calibration
,
1981
.
[7]
Zhao Kai.
Study of Noise Coupled Digital Auto-Gain Compensative Microwave Radiometer
,
2007
.