ETSI EN 301 215-3-2001 Fixed Radio Systems Point to Multipoint Antennas Antennas for Point-to-Multipoint Fixed Radio Systems in the 11 GHz to 60 GHz Band Part 3 Multipoint Multimed_1.pdf

1、ETSI EN 301 215-3 1.1.1 (2001-08) European Standard (Telecommunications series) Fixed Radio Systems; Point to Multipoint Antennas; Antennas for point-to-multipoint fixed radio systems in the 11 GHz to 60 GHz band; Part 3: Multipoint Multimedia Wireless System in 40,5 GHz to 433 GHz 2 ETSI EN 301 215

2、-3 V1.l.l (2001-08) Reference DENITM-04057-3 Keywords antenna, DRRS, multipoint, radio, RLL, transmission ETSI 650 Route des Lucioles F-O6921 Sophia Antipolis Cedex - FRANCE Tel.: +33 4 92 94 42 O0 Fax: +33 4 93 65 47 16 Siret No 348 623 562 O0017 - NAF 742 C Association but non lucratif enregistre

3、la Sous-prfecture de Grasse (06) No 7803/88 Important notice Individual copies of the present document can be downloaded from: htt!x/w.ettlsi. orq The present document may be made available in more than one electronic version or in print. In any case of existing or perceived difference in contents b

4、etween such versions, the reference version is the Portable Document Format (PDF). In case of dispute, the reference shall be the printing on ETSI printers of the PDF version kept on a specific network drive within ETSI Secretariat. Users of the present document should be aware that the document may

5、 be subject to revision or change of status. Information on the current status of this and other ETSI documents is available at If you find errors in the present document, send your comment to: ed itor.etsi .fr Copyright Notification No part may be reproduced except as authorized by written permissi

6、on. The copyright and the foregoing restriction extend to reproduction in all media. O European Telecommunications Standards Institute 2001. All rights reserved. ETSI 3 ETSI EN 301 215-3 V1.l.l (2001-08) Contents Intellectual Property Rights 4 Foreword 4 1 Scope 5 2 References 5 3 Definitions. symbo

7、ls and abbreviations . 5 4 Electrical characteristics . 6 4.1 Terminal Station antennas 6 4.1.1 TS radiation pattern envelope . 6 4.1.2 TS minimum antenna boresight gain . 8 4.2 Central station sectored antennas . 9 4.2.1 CS azimuth radiation pattern envelopes, sectored 9 4.2.2 Minimum boresight gai

8、n, sectored 12 4.3 Central station sectored elevation WES . 12 4.4 Central Station omni-directional antennas 13 4.4.1 CS Omni Elevation WES . 13 4.4.1.1 Symmetric elevation RPEs 14 4.4.1.2 Asymmetric elevation patterns 14 4.5 Polarization, terminal station and central station antennas . 15 4.6 Radom

9、es . 15 5 Conformance Tests . 15 Annex A (informative): Bibliography . 16 History . 17 ETSI 4 ETSI EN 301 215-3 V1.l.l (2001-08) Intellectual Property Rights IPRs essential or potentially essential to the present document may have been declared to ETSI. The information pertaining to these essential

10、IPRs, if any, is publicly available for ETSI members and non-members, and can be found in ETSI SR O00 3 14: “Intellectual Property Rights (IPRs); Essential, orpotentially Essential, IPRs notjed to ETSI in respect OfETSIstandards“, which is available from the ETSI Secretariat. Latest updates are avai

11、lable on the ETSI Web server (htt:/!wvw.etsi ordj r). Pursuant to the ETSI IPR Policy, no investigation, including IPR searches, has been carried out by ETSI. No guarantee can be given as to the existence of other IPRs not referenced in ETSI SR O00 3 14 (or the updates on the ETSI Web server) which

12、are, or may be, or may become, essential to the present document. Foreword This European Standard (Telecommunications series) has been produced by ETSI Technical Committee Transmission and Multiplexing (TM). The present document is part 3 of a multi-part deliverable covering requirements for antenna

13、s in conjunction with multipoint (MP) systems necessary to facilitate frequency Co-ordination between services in the frequency bands 11 GHz to 60 GHz. as identified below: Part 1 : “General aspects“; Part 2: “24 GHz to 30 GHz“; Part 3: Part 4: “Multipoint Multimedia Wireless system in 40,5 GHz to 4

14、3,5 GHz“; “Multipoint Multimedia Wireless system in 30 GHz to 40,5 GHz“. The present document is organized in the following way. Part 1 gives general information about the scope, normative references, definitions, classification, normative and informative electrical and mechanical characteristics. P

15、art 1 is the framework for fkther parts, where distinct values of normative characteristics for a given frequency sub-band are defined. Consequently, Part 1 in combination with another part forms the EN for a given sub-band. National transposition dates Date of adoption of this EN: Date of latest an

16、nouncement of this EN (doa): Date of latest publication of new National Standard or endorsement of this EN (dop/e): Date of withdrawal of any conflicting National Standard (dow): 13 July 2001 3 1 October 200 1 30 April 2002 30 April 2002 ETSI 5 ETSI EN 301 215-3 V1.l.l (2001-08) 1 Scope The present

17、document specifies the essential electrical requirements for linear polarization, fixed beam antennas to be utilized with new multipoint (P-MP and MP-MP) Multimedia Wireless Systems (MWS), including central station, repeater and terminal station applications, operating in frequency bands from 11 GHz

18、 to 60 GHz. These systems use various multiple access schemes. Antennas may be aligned manually, by electromechanical or by switching between a set of antennas. Electronically steered antenna arrays, and circularly polarized antennas are not considered in the present document. The present document,

19、taken together with EN 301 215-1 5, specifies the requirements for MWS (Multimedia Wireless Systems) 3 operating in the frequency range 40,5 GHz to 433 GHz. A Regulatory Authority may impose tighter requirements than the minimum values given in the present document, in order to maximize the use of s

20、carce spectrum resources. For some high gain multipoint requirements, antennas may be used having performance as per the appropriate point-to-point antenna standard. For these antennas, minimum requirements are given in 2. 2 Re fe re nces The following documents contain provisions which, through ref

21、erence in this text, constitute provisions of the present document. References are either specific (identified by date of publication, edition number, version number, etc.) or non-specific. For a specific reference, subsequent revisions do not apply. For a non-specific reference, subsequent revision

22、s do apply. il Void. Pl ETSI EN 300 833: “Fixed Radio Systems; Point-to-point Antennas; Antennas for point-to-point fixed radio systems operating in the frequency band 3 GHz to 60 GHz“. CEPT ERC/DEC/(99) 15: “ERC Decision of 1 June 1999 on the designation of the harmonised frequency band 40.5 to 43.

23、5 GHz for the introduction of Multimedia Wireless Systems (MWS) including Multipoint Video Distribution Systems (MVDS)“. ETSI EN 301 126-3-2: “Fixed Radio Systems; Conformance testing; Part 3-2: Point-to-Multipoint antennas - Definitions, general requirements and test procedures“. ETSI EN 30 1 2 15-

24、1 : “Fixed Radio Systems; Point-to-multipoint Antennas; Antennas for point-to-multipoint fixed radio systems in the 11 GHz to 60 GHz band; Part 1: General aspects“. 31 41 51 3 Definitions, symbols and abbreviations For the purposes of the present document, the definitions symbols and abbreviations g

25、iven in EN 3 O 1 2 15- 1 5 apply. ETSI 6 ETSI EN 301 215-3 V1.l.l (2001-08) Angle (degree) O 4 Electrical characteristics Co-polar Angle Crocc- (dB) (degree) polar (dB) O O -30 4.1 Terminal Station antennas The WES and gain parameters apply for both horizontal and vertical linearly polarized antenna

26、s. 4.1.1 TS radiation pattern envelope The Co-polar and cross-polar radiation patterns for both azimuth and elevation, shall not exceed the WE(s) defined in the following list: Class TS1: The gain values defined are all relative to maximum, actual gain at the measurement fieauencv. table la, figure

27、la O m -10 n S- 5 -20 c3 a, .? -30 li -40 - 50 . 1111i O 20 40 60 80 100 120 140 160 180 Angle relative to main beam ax is, degree Figure la: Class TSI terminal station antenna Table la: Class TSI ETSI 7 8 ETSI EN 301 215-3 V1.l.l (2001-08) -1 7 10 -30 Class TS2: The gain values defined are all rela

28、tive to maximum, actual gain at the measurement fieauencv. table lb, figure lb 90 1 O0 180 O -5 -1 o -15 m .i -20 5 2 -35 -25 c -30 m - : ;I -50 O 20 40 60 80 100 120 140 160 180 Angle relative to main beam axis, degree -30 1 O0 -35 -35 180 -37 -37 Figure 1 b: Class TS2 terminal station antenna Tabl

29、e 1 b Class TS2 I Angle I Co-polar I Angle I Cross- I Class TS3: The gain values defined are all relative to maximum, actual gain at the measurement fieauencv. table IC, figure IC O -10 i -20 (3 .2 -30 C al m c - I? -40 -50 O 20 40 60 80 100 120 140 160 180 Angle relative to main beam axis, degree F

30、igure IC: Class TS3 terminal station antenna ETSI 8 ETSI EN 301 215-3 V1.l.l (2001-08) Angle (degree) O Co-polar Angle Cross- (dB) (degree) polar (dB) O O -30 I 2 I O I 2 I -30 I 8 30 90 1 O0 -1 7 2 -20 -22 5 -20 -30 10 -30 -35 90 -30 180 Class TS4: The gain values defined are all relative to maximu

31、m, actual gain at the measurement fieauencv. table Id, figure Id -40 1 O0 -35 180 -40 O m -10 Z -20 -30 rn C 13 al m - t? -40 -50 (degree) O 23 I I I I I I I I I (dB) (degree) polar (dB) O O -30 O 10 -30 O 20 40 60 80 100 120 140 160 180 Angle relative to main beam axis, degree 10 Figure Id: Class T

32、S4 terminal station antenna -1 7 20 -45 Table Id: Class TS4 90 I Angle I Co-polar I Angle I Cross- I -40 180 -40 4.1.2 TS minimum antenna boresight gain The minimum gain of the TS antenna, expressed relative to an isotropic radiator, shall be for: - - Gain Category 1: 24 dBi; Gain Category 2: 28 dBi

33、. ETSI 9 PO PI ETSI EN 301 215-3 V1.l.l (2001-08) (degree) (dB) O O a+5 O 4.2 Central station sectored antennas P2 4.2.1 CS azimuth radiation pattern envelopes, sectored The CS azimuth templates for sectored (i.e. not omni) antennas are defined in the following list: - - - Class CS1: table 2, figure

34、 2 for sector angles in the range 15“ to 130“; Class CS2: table 3, figure 3 for sector angles in the range 15“ to 180“; Class CS3: table 4, figure 4 for sector angles in the range 15“ to 180“. The templates shall apply for all frequencies in the 40,5 GHz to 433 GHz band. Both Co-polar and cross-pola

35、r patterns are defined. The sector angle defined as 2a 5, shall be declared by the supplier. The gain values defined are all relative to the maximum gain in the declared sector angle. 2a + 5 -1 o 1 P3 P4 P5 5 c m E C m 13 135 -12 155 -15 180 -25 Q2 Q3 Cross-polar Angle (degree) b) QO O QI cy I I Ang

36、le off zero degree reference (deg) Relative Gain (dB) -22 -22 Figure 2: Normalized CSl sector antenna template for azimuth Q2 a+ 15 -25 Q3 180 -25 ETSI 10 Q4 Q5 ETSI EN 301 215-3 V1.l.l (2001-08) Co-polar PO PI P2 P3 P4 P5 Q2 Angle Relative Gain (degree) (dB) O O a+5 O a+ 15 -20 110 -23 140 -35 180

37、-35 Cross-polar Angle (degree) QO O QI a Q2 a+ 15 Q3 105 Q4 140 Figure 3: Normalized CS2 sector antenna template for azimuth Relative Gain (dB) -25 -25 -30 -30 -35 Table 3: Class CS 2 Q5 180 -35 ETSI 11 ETSI EN 301 215-3 V1.l.l (2001-08) Angle off zero degree reference (deg) Figure 4: Normalized CS3

38、 sector antenna template for azimuth Table 4: Class CS 3 ETSI 12 ETSI EN 301 215-3 V1.l.l (2001-08) 4.2.2 Minimum boresight gain, sectored The CS sectored antenna boresight gain shall exceed the boundaries defined in figure 5 as a function of sector angle 2a, in the range 15“ to 180“ and for all fre

39、quencies in the 40,5 GHz to 433 GHz frequency range. Antenna boresiht gain does not necessarilv correspond to the O“ - reference gain. 10 30 50 70 90 110 130 150 170 Sector Angle , degree Figure 5: CS sector antenna boresight minimum gain 4.3 Central station sectored elevation RPEs One symmetric CS

40、antenna elevation WE is defined in figure 6. Asymmetric elevation patterns are not presently covered in the present document. For antennas designed without any tilt the O“ reference direction normally corresponds to the boresight direction. It may be necessary in practical deployments to use electri

41、cal or mechanical tilt, or a combination of these two, to achieve the required cell coverage, taking into account the surrounding terrain, for example. The elevation pattern is considered appropriate to the commonly used range of O“ to - 1 O“ for electrical downtilt. A fwther mechanical downtilt of

42、up to I 10“ may be suitable for some situations. An electrical tilt is translated onto the corresponding pattern as a 8“ shift along the elevation angle axis. NOTE: Positive angles are for above boresight (up) and negative angles are for below (down). O -5 $ -10 .E -15 -20 5 c -25 B -30 -35 m m - O

43、10 20 30 40 50 60 70 80 90 Elevation angle relative to main beam axis , degree Figure 6: Symmetric CS antenna co-polar elevation RPE ETSI 13 ETSI EN 301 215-3 V1.l.l (2001-08) Elevation Angle (degrees) n Co-polar (dB) n 6 15 90 The Co-polar limit in figure 6 shall be linearly interpolated beyond the

44、 -25 dB, 90“ point out to the point defined at 180“ by the appropriate azimuth Class of antennas described in tables 2,3 and 4. The cross-polar limit shall be linearly interpolated between the O“ point and the 180“ point from the appropriate azimuth Class of antennas described in tables 2,3 and 4. O

45、 -15 -25 4.4 Central Station omni-directional antennas For omni-directional Central Station (CS) antennas the following parameters shall apply for all frequencies in the 40,5 GHz to 433 GHz band: - minimum nominal gain: 8 dBi; - gain ripple (azimuth): 3 dB maximum (peak-to-peak); - cross-polar discr

46、imination: 20 dB minimum. 4.4.1 CS Omni Elevation RPEs Two CS antenna elevation WES are defined: - - one for antennas designed to exhibit symmetric WES about the O“ reference direction (table 6); and one for antennas designed for asymmetric WES (table 7). For antennas designed without any tilt the z

47、ero degree reference direction normally corresponds to boresight. It may be necessary in practical deployments to use electrical or mechanical tilt, or a combination of these two, to achieve the required cell coverage, taking into account the surrounding terrain, for example. These elevation pattern

48、s are considered appropriate to the commonly used range of O“ to -10“ for electrical down-tilt. An electrical tilt is translated onto the corresponding pattern as a f shift along the elevation angle axis. NOTE: Positive angles are for above boresight (up) and negative angles are for below (down). ET

49、SI 14 Angle (degrees) Co-polar (dB) Angle (degrees) O O O 8 O 90 30 -1 o cin -70 ETSI EN 301 215-3 V1.l.l (2001-08) Cross-polar (dB) -20 -20 4.4.1.1 Symmetric elevation RPEs For omni-symmetric antennas the Co-polar limits shown in figure 7 and in table 6 shall apply, with a uniform value of -20 dB for the cross-polar limit. -25 O 20 40 60 80 Angle relative to main beam axis, degree Figure 7: Symmetric CS Antenna Elevation Patterns Table 6: Symmetric CS Antenna Elevation Patterns 4.4.1.2 As y m metric e I eva t i o n pat terns For omni-asy