308 ATTENUATION OF RADIO WAVES 



7.14. References 



[1] Bussey, H. E. (Aug. 1950), Microwave attenuation statistics estimated from 



rainfall and water vapor, Proc. IRE 38, No. 7, 781. 

 [2] Davidson, D., and A. Pote (Dec. 1955), Designing over-horizon communication 



links. Electronics, 28, 126. 

 [3] Bean, B. R., and R. Abbott (May-Aug. 1957), Oxygen and water vapor absorp- 

 tion of radio waves in the atmosphere, Geofis. Pura Appl. 37, 127-144. 

 [4] Van Vleck, J. H. (Apr. 1947), Absorption of microwaves by oxygen, Phys. Rev. 



71, 413-424. 

 [5] Van Vleck, J. H. (Apr. 1947), The absorption of microwaves by uncondensed 



water vapor, Phys. Rev. 71, 425-433. 

 [6] Van Vleck, J. H. (1951), Theory of absorption by uncondensed gases. Book, 



Propagation of Short Radio Waves, pp. 646-664 (McGraw-Hill Book Co., Inc., 



New York, N.Y.). 

 [7] Becker, G. B., and S. H. Autler (Sept. 1, 15, 1946), Water vapor absorption of 



electromagnetic radiation in the centimeter wavelength range, Phys. Rev. 70, 



Nos. 5 and 6, 300-307. 

 [8] Birnbaum, G., and A. A. Maryott (Sept. 15, 1955), Microwave absorption in 



compressed oxygen, Phys. Rev. 99, 1886. 

 [9] Artman, J. O., and J. P. Gordon (Dec. 1954), Absorption of microwaves by oxygen 



in the millimeter wavelength region, Phys. Rev. 96, No. 5, 1237-1245. 

 [10] Tinkham, M., and M. W. P. Strandberg (July 15, 1955), Line breadths in the 



microwave magnetic resonance spectrum of oxygen, Phys. Rev. 99, No. 2, 



537-539. 

 [11] Hill, R. M., and W. Gordy (Mar. 1954), Zeeman effect and line breadth studies 



of the microwave lines of oxygen, Phys. Rev. 93, 1019. 

 [12] Artman, J. O. (1953), Absorption of microwaves by oxygen in the millimeter 



wavelength region, Columbia Radiation Lab. Rept. (Columbia Univ. Press, 



New York, N.Y.). 

 [13] Straiton, A. W., and C. W. Tolbert (May 1960), Anomalies in the absorption of 



radio waves by atmospheric gases, Proc. IRE 48, No. 5, 898-903. 

 [14] Tolbert, C. W., and A. W. Straiton (Apr. 1957), Experimental measurement of 



the absorption of millimeter radio waves over extended ranges, IRE Trans. 



Ant. Prop. AP-5, No. 2, 239-241. 

 [15] Gunn, K. L. S., and T. W. R. East (Oct.-Dec. 1954), The microwave properties of 



precipitation particles. Quart. J. Roy. Meteorol. Soc. 80, 522-545. 

 [16] Bean, B. R., and B. A. Cahoon (Sept. 1957), A note on the climate variation of 



absolute humidity, Bull. Am. Meteorol. Soc. 28, No. 7, 395-398. 

 [17] Ratner, B. (1945), Upper air average values of temperature, pressure, and relative 



humidity over the United States and Alaska (U.S. Weather Bureau). 

 [18] Donaldson, Ralph J., Jr. (June 1955), The measurement of cloud liquid-water 



content by radar, J. Meteorol. 12, No. 3, 238-244. 

 [19] Weickmann, H. K., and H. J. aufm Kampe (June 1953), Physical properties of 



cumulus clouds, J. Meteorol. 10 204-221. 

 [20] Battan, L. J. (1959), Radar Meteorology, Book, p. 43 (Univ. of Chicago Press, 



Chicago, 111.). 

 [21] Ryde, J. W., and D. Ryde (1945), Attenuation of centimeter waves by rain, hail, 



fog, and clouds (General Electric, Wembly, England). 

 [22] Laws, J. O., and D. A. Parsons (Apr. 1943), The relationship of raindrop size to 



intensity. Trans. Am. Geophys. Union, 24th Annual Meeting, 452-460. 

 [23] Ryde, J. W. (1946), The attenuation and radar echoes produced at centimetre 



wave-lengths by various meteorological phenomena. Meteorological Factors in 



Radio Wave Propagation, pp. 169-188 (The Physical Society, London, England). 



