Committee on Radio Astronomy Frequencies

The Committee on Radio Astronomy Frequencies (CRAF) is a committee of the European Science Foundation (ESF).

Frequency band allocated to the Radio Astronomy Service:

• ITU-RR allocations (+ footnotes)
• National Arrangements for Radio Astronomy different from ITU-R Radio Regulations
• Astrophysical importance of the band 14.47 - 14.5 GHz
• Threshold levels of interference detrimental to radio astronomy
• Radio Astronomy use of this band in Europe
• Threats to the Radio Astronomy Service

ITU-RR allocations (+ footnotes):

14.4  - 14.47  GHz:	FIXED
			FIXED-SATELLITE (Earth-to-space) 5.457A 5.457B 5.484A 5.506 5.506B
			MOBILE except aeronautical mobile
			Mobile-Satellite (Earth-to-space) 5.506A 5.509A
		 	Space Research (space-to-Earth)

			5.504A
			
			
14.47  - 14.5  GHz:	FIXED
			FIXED-SATELLITE (Earth-to-space) 5.457A 5.457B 5.484A 5.506 5.506B
			MOBILE except aeronautical mobile
			Mobile-Satellite (Earth-to-space) 5.506A 5.504B 5.509A
		 	Radio Astronomy
		 	
		 	5.149 5.504A
		 	
		 	
14.5   - 14.8  GHz:	FIXED
			FIXED-SATELLITE (Earth-to-space) 5.510
			MOBILE 
			Space Research
			

National Arrangements for Radio Astronomy different from ITU-R Radio Regulations:

• Armenia: no allocation
• Austria: no allocation - only mention of No. 5.149
• Belgium: no allocation
• Estonia: no allocation
• Finland: no allocation
• Iceland: no allocation
• Ireland: no allocation
• Liechtenstein: no allocation
• Luxembourg: no allocation
• Poland: no allocation
• Russian Federation: no allocation
• Sweden: no allocation
• Turkey: no allocation
• United Kingdom: no protection or reference to No. 5.149

Astrophysical importance of the band 14.47 - 14.5 GHz

The frequency band 10 to 15 GHz provides some of the best angular resolutions (~2 arc minutes) using many large and accurate radio telescopes. Many of the nonthermal synchrotron sources are just detectable at higher frequencies, and this frequency range gives us observational information at the highest frequency where these can be detected reliably. This high-frequency range is also important for monitoring the intensity variability of the enigmatic quasars. These objects, which could be the farthest celestial objects that we can detect and which produce surprisingly large amounts of energy, have been found to vary in intensity with periods of weeks and months. Such observations lead to estimates of the sizes of these sources, which turn out to be very small for the amount of energy they produce. The variability of quasars (and some peculiar galaxies) is more pronounced at high frequencies and observations at such frequencies facilitate the discovery and the monitoring of such events. The energy emitted during any one burst from a quasar is equivalent to completely destroying a few hundred million stars in a period of a few weeks or months. We do not yet understand the fundamental physics that can produce such events - observations of the size and variability of these sources are the only ways that can assist us in solving such problems. Such observations are now best performed in the frequency range 10 to 15 GHz.

At 14.4885 GHz an important formaldehyde (H₂CO) line exists, which has been observed in the direction of many galactic sources. Since these lines originate from the upper levels of ortho-formaldehyde their study gives valuable information on the physical conditions of the interstellar medium, because the excitation energies required to produce such lines are different from the energies required to produce the H₂CO lines observed at 4829.66 MHz.

Threshold levels of interference detrimental to radio astronomy spectral-line observations:

	System Sensitivity (noise fluctuations)		Threshold Interference Levels
	Temperature	Power Spectral Density	Input Power	Power Flux Density	Spectral Power Flux Density
Single Dish	1.73 mK	-256 dB W Hz-1	-214 dB W	-169 dB W m-2	-221 dB W m-2 Hz-1

Threshold levels of interference detrimental to radio astronomy continuum observations:

	System Sensitivity (noise fluctuations)		Threshold Interference Levels
	Temperature	Power Spectral Density	Input Power	Power Flux Density	Spectral Power Flux Density
Single Dish	0.095 mK	-269 dB(WHz-1)	-202 dBW	-156 dB(Wm-2)	-233 dB(Wm-2Hz-1)
VLBI					-188 dB(Wm-2Hz-1)

NOTE:

For further details the reader is referred to ITU-R Recommendation RA769. It should, however, be noted that the observed spectral power flux densities are much lower than the harmful interference levels because they are made in the main beam of the radio astronomy antennas whereas the harmful levels correspond to reception in the sidelobes, i.e. the differences are related to the gain of the antennas. The differences can be of the order of 50 to 80 dB W m^-2 Hz^-1 (see ITU-R "Handbook on Radio Astronomy", 1995/2003, chapter 4).

In Europe, the band 14.47 - 14.5 GHz is used by the Radio Astronomy Service in:

• Germany
• Russia
• Turkey
• United Kingdom

Threats to the Radio Astronomy Service:

Sharing problems with the following services:

• Fixed Service
• Fixed-Satellite Service
• Mobile Service

  Out-of-band emissions from the following services:

• Fixed Service
• Fixed-Satellite Service
• Mobile Service