ITU-R BO 1659-1-2012 Mitigation techniques for rain attenuation for broadcasting-satellite service systems in frequency bands between 17 3 GHz and 42 5 GHz《频段为17 3 GHz-42 5 GHz广播卫星.pdf

1、 Recommendation ITU-R BO.1659-1(01/2012)Mitigation techniques for rain attenuation for broadcasting-satellite service systems in frequency bands between17.3 GHz and 42.5 GHzBO SeriesSatellite deliveryii Rec. ITU-R BO.1659-1 Foreword The role of the Radiocommunication Sector is to ensure the rational

2、, equitable, efficient and economical use of the radio-frequency spectrum by all radiocommunication services, including satellite services, and carry out studies without limit of frequency range on the basis of which Recommendations are adopted. The regulatory and policy functions of the Radiocommun

3、ication Sector are performed by World and Regional Radiocommunication Conferences and Radiocommunication Assemblies supported by Study Groups. Policy on Intellectual Property Right (IPR) ITU-R policy on IPR is described in the Common Patent Policy for ITU-T/ITU-R/ISO/IEC referenced in Annex 1 of Res

4、olution ITU-R 1. Forms to be used for the submission of patent statements and licensing declarations by patent holders are available from http:/www.itu.int/ITU-R/go/patents/en where the Guidelines for Implementation of the Common Patent Policy for ITU-T/ITU-R/ISO/IEC and the ITU-R patent information

5、 database can also be found. Series of ITU-R Recommendations (Also available online at http:/www.itu.int/publ/R-REC/en) Series Title BO Satellite delivery BR Recording for production, archival and play-out; film for television BS Broadcasting service (sound) BT Broadcasting service (television) F Fi

6、xed service M Mobile, radiodetermination, amateur and related satellite services P Radiowave propagation RA Radio astronomy RS Remote sensing systems S Fixed-satellite service SA Space applications and meteorology SF Frequency sharing and coordination between fixed-satellite and fixed service system

7、s SM Spectrum management SNG Satellite news gathering TF Time signals and frequency standards emissions V Vocabulary and related subjects Note: This ITU-R Recommendation was approved in English under the procedure detailed in Resolution ITU-R 1. Electronic Publication Geneva, 2012 ITU 2012 All right

8、s reserved. No part of this publication may be reproduced, by any means whatsoever, without written permission of ITU. Rec. ITU-R BO.1659-1 1 RECOMMENDATION ITU-R BO.1659-1 Mitigation techniques for rain attenuation for broadcasting-satellite service systems in frequency bands between 17.3 GHz and 4

9、2.5 GHz (2003-2012) Scope This Recommendation provides techniques to mitigate rain attenuation that should be considered in order to facilitate the introduction of BSS systems in frequency bands between 17.3 GHz and 42.5 GHz. Such techniques include increase in e.i.r.p., hierarchical transmission an

10、d broadcasting system assuming storage in receiver. The ITU Radiocommunication Assembly, considering a) that BSS systems using frequency bands from 17.3 GHz onwards have the possibility to deliver wide-RF-band digital multiprogramme services, which may consist of high-definition television (HDTV), a

11、udio and data programmes, possibly including interactivity; b) that, in the future, they can also be the appropriate channels to accommodate the higher bit-rate programmes, such as extremely high resolution imagery whose number of lines is much larger than HDTV, three-dimensional TV and high bit-rat

12、e data programmes; c) that the frequency allocations were made to the BSS by the World Administrative Radio Conference (Geneva, 1979) (WARC-79) in the 42 GHz and 84 GHz band, World Administrative Radio Conference for Dealing with Frequency Allocations in Certain Parts of the Spectrum (Malaga-Torremo

13、linos, 1992) (WARC-92) allocated the band 17.3-17.8 GHz in Region 2 and the band 21.4-22.0 GHz in Regions 1 and 3 to BSS to be implemented after 1 April 2007, and the frequency allocation modification to the BSS from the 84 GHz band to the 74 GHz band was made by the World Radiocommunication Confere

14、nce (Istanbul, 2000) (WRC-2000); d) that the atmospheric absorption and rain attenuation in the BSS bands from 17.3 GHz onwards are much larger than those in the 12 GHz band which is widely used for BSS; e) that the propagation attenuation may place a heavy restriction on service availability and/or

15、 system feasibility; f) that Report ITU-R BO.2007 describes technical information to introduce BSS into the 17/21 GHz band with reference to Resolution 525 (WARC-92). In the Annexes to this Report, detailed information is given such as: possible coding and modulation approaches to improve service av

16、ailability for digital HDTV satellite broadcasting; an adaptive satellite e.i.r.p. control method for the 21 GHz band satellite broadcasting; bandwidth efficient coding and modulation schemes for wideband HDTV applications supported by satellite and cable networks, 2 Rec. ITU-R BO.1659-1 recommends

17、1 that the use of one of the following techniques to mitigate the rain attenuation or a combination of these techniques should be considered to facilitate the introduction of the BSS systems in frequency bands between 17.3 GHz and 42.5 GHz: increase in e.i.r.p. (see Annex 1); hierarchical transmissi

18、on (see Annex 2); broadcasting system assuming storage in receiver (see Annex 3). NOTE 1 Supplementary information related to the rain attenuation in the BSS bands between 17.3 GHz and 42.5 GHz and some prospective feeder-link bands between 17.3 GHz and 30 GHz is found in Appendix 1. Annex 1 Increas

19、e in e.i.r.p. 1 Concept of variable e.i.r.p. satellite Adaptive power control is an effective and straightforward method to enhance the service availability under rain fade, while it reduces interference to the other services in the clear-sky condition. The BSS system normally has a large service ar

20、ea covered by a single beam. The variable e.i.r.p. systems are categorized as to whether the e.i.r.p. can be locally-variable within the service area or not. 1.1 Uniformly-variable e.i.r.p. In the system, total output power of the beam is controlled, while the antenna pattern is left unchanged. The

21、e.i.r.p. in the service area varies uniformly. Typically, strong rains occur locally. To compensate for local rain attenuation, the e.i.r.p. is increased for the whole coverage area. Apart from areas with strong rain, the rest of the service area in clear-sky conditions can be overcompensated. It is

22、 undesirable from the viewpoint of sharing with the other systems. In this respect, the adaptive power control of such single beam systems is less effective than those of multibeam systems. The total required radiation power is high and the increase in radiation power is frequent since the single be

23、am covers the whole region. The concept of the system is shown in Fig. 1. The following parameters are used for the definition of the system: e.i.r.p. value ENwith nominal condition in the service area; e.i.r.p. value EMwith maximum e.i.r.p. increase in the service area. The e.i.r.p. values in certa

24、in areas vary, ranging from ENto EM. Rec. ITU-R BO.1659-1 3 FIGURE 1 Concept of uniformly variable e.i.r.p. Service area Service areae.i.r.p. = ENe.i.r.p.High rainfall rate(hatched area)Increase in e.i.r.p.of whole regione.i.r.p.e.i.r.p. = EMEMENE ENMAlternatively, the following parameters can be us

25、ed to define the system from the viewpoint of satellite design: nominal power supplied to the input of the antenna; maximum power supplied to the input of the antenna; gain contour of the antenna. 1.2 Locally-variable e.i.r.p. The locally-variable e.i.r.p. system varies the distribution of the satel

26、lite e.i.r.p. of a beam within the service area locally, in accordance with the local distribution of rain attenuation. Total required radiation power of the satellite is to be reduced compared with a uniformly-variable e.i.r.p. system with the same service availability, because the probability of s

27、imultaneous occurrence of strong rain in a large portion of the service area is considered to be substantially low. Therefore a more stringent level of the spurious emission limitation is applied. While a high e.i.r.p. may be required to compensate for large rain attenuation, the area and the durati

28、on of the boost are limited. Since the e.i.r.p. can be lowered for the area and duration with low rain attenuation, it has an advantage over satellite systems with a fixed or uniformly-variable e.i.r.p. in terms of sharing with other systems. The concept of the system is shown in Fig. 2. The followi

29、ng parameters are used for the definition of the system: e.i.r.p. value ENfor the area with nominal condition (EN); e.i.r.p. value EMfor the local area with maximum e.i.r.p. increase (EM). 4 Rec. ITU-R BO.1659-1 FIGURE 2 Concept of locally-variable e.i.r.p. Service areaService areae.i.r.p. = E Ne.i.

30、r.p.High rainfall rate(hatched area)Increase in e.i.r.p.of rain regionEnvelopee.i.r.p.e.i.r.p. = E NENEMENE ENMe.i.r.p. = EM Alternatively, the following parameters can be used to define the system from the viewpoint of satellite design: nominal power supplied to the input of the antenna; nominal an

31、tenna gain contour; maximum power supplied to the input of the antenna; examples of antenna gain contour with local increase; envelope of maximum antenna gain with the results of all possible movement of intensified e.i.r.p. 2 Satellite technologies 2.1 Satellite technologies for uniformly-variable

32、e.i.r.p. The system may be realized with a combination of a reflector antenna with a horn feeder and a variable-power high power amplifier (HPA). The HPA with considerably higher power will be employed to increase e.i.r.p. in the whole service area. The impact of the power control on the efficiency

33、of the HPA needs to be studied. 2.2 Satellite technologies for locally-variable e.i.r.p. The satellite antenna configurations shown in Table 1 can be used to realize the function. Rec. ITU-R BO.1659-1 5 TABLE 1 Antenna configurations for locally-variable e.i.r.p. systems Antenna type Multi-horn Phas

34、ed-array Single reflector Double reflector Direct radiation Schematic diagram Range of pattern synthesis Fixed beam location Limited beam steering angle Greater than single reflector Greatest Peak gain High Lower than double reflector Lower than multi-horn High Gain decrease with beam-steering Large

35、 Smaller than multi-horn Smaller than single reflector Small Number of element Small Medium Medium Large Complexity of structure Simple Medium Complex (sub-reflector) Complex (feed circuit) 2.2.1 Multi-horn antenna In the antenna, multiple feed horns are placed at the focal plane of the reflector. E

36、ach horn corresponds to one of the beams generated by the antenna. When each beam radiates in phase, the beams form a single shaped beam. By controlling the power provided to the individual horns, a locally-variable e.i.r.p. system can be realized. The range of power control is limited to the range

37、of the corresponding HPAs output power. The impact of the power control on the efficiency of the HPA needs to be studied. Since the locations of the beams are fixed, the range of possible pattern syntheses is less than those of phased-array antennas. 2.2.2 Phased-array antennas Compared with the mul

38、ti-horn antenna, a greater range of pattern syntheses can be obtained using phased-array antennas. The direct-radiation phased-array antenna would show best performance in terms of the range of possible pattern syntheses. On the other hand, the complexity of the configuration may reduce the applicab

39、ility to the on-board system. In contrast to the multi-horn antenna, a large number of the radiation elements contribute to the power control of a small area. The minimum diameter of the intensified area is determined by the aperture diameter of the antenna. The performance and feasibility of each c

40、onfiguration should be examined further. 2.2.3 Case study on antenna pattern synthesis with local increase An example of antenna synthesis is given to explain the feasibility of a locally-variable e.i.r.p. satellite. Its parameters are shown below: Antenna configuration: array-fed single reflector a

41、ntenna Aperture diameter of antenna: 10 m Frequency: 21.7 GHz Number of radiators: 227 6 Rec. ITU-R BO.1659-1 Interval of radiators: 1.5 wavelengths. The calculated antenna gain contours are shown in Fig. 3. The left-hand Figure shows a radiation pattern under nominal conditions. Taking advantage of

42、 the large aperture antenna and the phased-array technique, a radiation pattern with a large gain plateau is obtained. The right-hand Figure is an example of the radiation pattern with a local gain increase. The peak gain increases by more than 10 dB from the nominal value. As a result of the local

43、increase, gains in the remaining area slightly decrease. FIGURE 3 Example of pattern synthesis (simulation) b) Gain contour with local increaseAzimuth (degrees)1.5 2.5 3.5 4.5 5.53.54.55.56.57.5Elevation(degrees)a) Nominal gain contourAzimuth (degrees)1.5 2.5 3.5 4.5 5.53.54.55.56.57.5Elevation (deg

44、rees)41 dBInterval of contour: 3 dB Interval of contour: 3 dB41 dB52.3 dBAntenna parameters such as the diameter and the number of radiators should be determined by taking into consideration the system parameters such as size and shape of the service area, minimum and maximum area to be compensated

45、and required increase level as well as the feasibility of on-board equipment and the cost. 2.3 HPA technologies Travelling wave tubes (TWTs) and solid state power amplifiers (SSPAs) can be used for the HPA of the satellites. In the 17/21 GHz band, the overall efficiency of a conventional TWT with an

46、 output power around 100 W exceeds 60%. On the other hand, the output power and efficiency of SSPAs are lower than those of TWTs. To use TWTs as amplifiers for an active array antenna of locally-variable e.i.r.p. satellites, mini-TWTs, whose cross-sectional dimensions are reduced compared with the c

47、onventional one, have been studied. A comparison is shown in Table 2. Rec. ITU-R BO.1659-1 7 TABLE 2 Examples of HPAs for the 17/21 GHz band satellite systems Annex 2 Hierarchical transmission 1 Concept of hierarchical transmission Two or more modulation schemes of different C/N requirements are tim

48、e-multiplexed to form a hierarchical transmission signal. The fundamental information, such as minimum quality video signal and audio, is transmitted at a low data-rate by using a robust modulation/channel coding scheme with a low C/N requirement. On the other hand, the high data-rate signal part, s

49、uch as for HDTV or 5.1-channel surround sound, is transmitted by using a higher efficiency modulation scheme with a higher C/N requirement. The receiver chooses the appropriate data stream depending on the actual receiving C/N condition. Therefore, a hierarchical transmission can be used to realize a stepwise degradation in the digital system that degrade the picture quality gradually in accordance with the decrease in the receiving C/N. In the BSS bands from 17.3 GHz onwards, the rain attenuation is considerably higher than that in the 12