Antenna Integrated Radio Unit 6419 [PDF]

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Antenna Integrated Radio Unit Description AIR 6419 Description

Ge23266B

302/1551-LZA 701 6001/1 Uen Y

Copyright © Ericsson AB 2021, 2022. All rights reserved. No part of this document may be reproduced in any form without the written permission of the copyright owner. Disclaimer The contents of this document are subject to revision without notice due to continued progress in methodology, design and manufacturing. Ericsson shall have no liability for any error or damage of any kind resulting from the use of this document. Trademark List All trademarks mentioned herein are the property of their respective owners. These are shown in the document Trademark Information.

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Contents

Contents 1

Product Overview

1

1.1

Variants

1

2

Technical Data

2

2.1

Radio Capabilities

2

2.2

Output Power

2

2.3

EIRP Data

2

2.4

Physical Characteristics

8

2.5

Operating Environment

10

2.6

Wind Load

10

2.7

Heat Dissipation

10

2.8

Vibration

11

2.9

Acoustic Noise

11

2.10

Power Supply Characteristics

11

2.11

RF Electromagnetic Field Exposure

12

2.12

Software

16

2.13

Radio Configurations

16

3

Hardware Architecture

17

4

Installation Requirements

19

4.1

Outdoor Installation Environments to Avoid

19

4.2

Installation Alternatives

20

4.3

Space Requirements

21

4.4

Painting Disclaimer

22

5

Interfaces

23

5.1

Optical Cable Interfaces

25

5.2

DIN 14-Pin Interface

25

5.3

TX Monitor Interface (Optional)

26

5.4

−48 V DC Power Supply Interface

26

5.5

Grounding Interface

26

5.6

Optical Indicators

27

6

Standards and Regulations

28

6.1

Regulatory Approval

28

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Antenna Integrated Radio Unit Description

6.2

Other Standards and Regulations

31

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Product Overview

1

Product Overview AIR 6419 has the following main features: — Designed for outdoor use, for wall, pole, tower, or mast mounting — Mid band — NR and LTE TDD support, see Supported Radio Capabilities — Up to 64TX/64RX branches, see Supported Radio Capabilities — Mixed mode support, see Supported Radio Capabilities — Support for Massive MIMO, see Supported Radio Capabilities — Vertical and horizontal beamforming — Tilt and swivel support — EC light — The power connection supports 2-wire (DC-C)/3-wire (DC-I) — 2 eCPRI up to 25.8 Gbps per port — Basic Stand-alone Radio Installation Check support — Complies with 3GPP base station class Wide Area. For a list of relevant standards, see Radio Standards Compliance on page 30. The product is equipped with one or more warranty seal stickers. Note:

1.1

Seals that have been implemented by Ericsson must not be broken or removed, as it otherwise voids warranty.

Variants — AIR 6419 B40 — AIR 6419 B41 — AIR 6419 B42 — AIR 6419 B77G — AIR 6419 B78Y

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1

Antenna Integrated Radio Unit Description

2

Technical Data

2.1

Radio Capabilities For supported number of carriers, carrier bandwidth, operating bandwidth, IBW, frequency range, detailed RAT support, and mixed mode configurations, see Supported Radio Capabilities. Special considerations might apply for certain configurations, see Building Blocks.

Output Power

2.2

For maximum nominal output power, see Supported Radio Capabilities. Minimum configured output power without degradation in product performance is 20 W. Hardware Activation Codes (HWAC) are required for total output power over 20 W. For detailed information about output power hardware activation codes, see Hardware-Related Capabilities in the Radio Node libraries. For information about maximum output power per carrier type, see Radio Node Configurations.

EIRP Data

2.3

Traffic Beams Table 1

AIR 6419 Typical EIRP Performance Data for Traffic Beams

Product AIR 6419 B40

AIR 6419 B41

AIR 6419 B42

2

Uniform Traffic Beams(1)

Direction

Parameter

H0V6°

H55V6°

H0V19°

Vertical Beamwidth (°)

8

8

8.5

Horizontal Beamwidth (°)

14

22

14.5

Main Beam Peak EIRP (dBm)(2)(3)

2 × 76

2 × 73

2 × 74

Vertical Beamwidth (°)

7.5

7.5

7.5

Horizontal Beamwidth (°)

12.5

20

13

Main Beam Peak EIRP (dBm)(2)(3)

2 × 76.5

2 × 73.5

2 × 74.5

Vertical Beamwidth (°)

7

7

7

Horizontal Beamwidth (°)

12.5

20

13

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Technical Data

Uniform Traffic Beams(1)

Product

AIR 6419 B77G

AIR 6419 B78Y

Direction

Parameter

H0V6°

H55V6°

H0V19°

Main Beam Peak EIRP (dBm)(2)(3)

2 × 77

2 × 74

2 × 74

Vertical Beamwidth (°)

6.5

6.5

7

Horizontal Beamwidth (°)

12.5

20

13

Main Beam Peak EIRP (dBm)(2)(3)

2 × 76.5

2 × 73.5

2 × 74

Vertical Beamwidth (°)

6.5

6.5

6.5

Horizontal Beamwidth (°)

12

19.5

12.5

Main Beam Peak EIRP (dBm)(2)(3)

2 × 76.5

2 × 73

2 × 73.5

(1) The traffic beamforming of this product is not limited to the uniform beamshapes and directions given in the table. The beams are dynamically optimized. (2) The main beam peak EIRP in the table is calculated for two simultaneous orthogonal beams. (3) This value can be limited by the activation of certain features.

Broadcast Beams Table 2

AIR 6419 Typical Antenna Performance Data for Broadcast Beams in Macro Scenario

Product

AIR 6419 B40

AIR 6419 B41

AIR 6419 B42

Scenario: Macro

Beam LTE

Beam NR

Parameter

BrM1(1), BrM2(2)

BrM1(1)

Vertical Beamwidth (°)

8±1

8±1

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

−3 to 11

−3 to 11

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

15

15

Front to Back Ratio (dB)

25

25

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 69

1 × 72

Vertical Beamwidth (°)

7.5±1

7.5±1

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

−3 to 11

−3 to 11

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression Peak to 20° (dB)

15

15

Front to Back Ratio (dB)

25

25

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 68.5

1 × 72

Vertical Beamwidth (°)

7±1

7±1

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

−3 to 11

−3 to 11

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

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Antenna Integrated Radio Unit Description

Product

AIR 6419 B77G

AIR 6419 B78Y

Scenario: Macro

Beam LTE

Beam NR

Parameter

BrM1(1), BrM2(2)

BrM1(1)

Vertical Side Lobe Suppression (dB)

16

16

Front to Back Ratio (dB)

25

25

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 69.5

1 × 72.5

Vertical Beamwidth (°)

n/a

7±1

Horizontal Beamwidth (°)

n/a

65±5

Digital Downtilt (°)

n/a

−3 to 11

Vertical Beam Pointing Error (°)

n/a

≤1

Horizontal Beam Pointing (°)

n/a

0±5

Vertical Side Lobe Suppression (dB)

n/a

16

Front to Back Ratio (dB)

n/a

25

Beam Parallelity (BrM1●BrM2) (dB)

n/a

-

EIRP (Typical) (dBm)

n/a

1 × 72

Vertical Beamwidth (°)

6.5±1

6.5±1

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

−3 to 11

−3 to 11

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

>12

>12

Front to Back Ratio (dB)

25

25

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

-

EIRP (Typical) (dBm)

2 × 69

1 × 72

(1) Broadcast Beam Macro 1 (2) Broadcast Beam Macro 2

Table 3 AIR 6419 Typical Antenna Performance Data for Broadcast Beams in Macro HSLS Scenario Product

AIR 6419 B41

Scenario: Macro

Beam LTE

Beam NR

Parameter

BrM1(1), BrM2(2)

BrM1(1)

Vertical Beamwidth (°)

7.5±1

7.5±1

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

−3 to 11

−3 to 11

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression Peak to 20° (dB)

16

16

First Vertical Side Lobe Suppression (dB)

20

20

Front to Back Ratio (dB)

25

25

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 67.5

1 × 71

(1) Broadcast Beam Macro 1

4

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Technical Data

(2) Broadcast Beam Macro 2

Table 4

AIR 6419 Typical Antenna Performance Data for Broadcast Beams in Hotspot Scenario

Product

AIR 6419 B40

AIR 6419 B41

AIR 6419 B42

AIR 6419 B77G

AIR 6419 B78Y

Scenario: Hotspot

Beam LTE

Beam NR

Parameter

BrHS1(1), BrHS2(2)

BrHS1(1)

Vertical Beamwidth (°)

28.5±3

28.5±3

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

14

14

Front to Back Ratio (dB)

−

−

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 64

1 × 67

Vertical Beamwidth (°)

30±3

30±3

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤3

≤3

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

12

12

Front to Back Ratio (dB)

−

−

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 64

1 × 67

Vertical Beamwidth (°)

27±3

27±3

Horizontal Beamwidth (°)

65±5

65±5

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

11

11

Front to Back Ratio (dB)

−

−

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 64.5

1 × 67.5

Vertical Beamwidth (°)

n/a

27±3

Horizontal Beamwidth (°)

n/a

65±5

Digital Downtilt (°)

n/a

Fixed 6

Vertical Beam Pointing Error (°)

n/a

≤2

Horizontal Beam Pointing (°)

n/a

0±5

Vertical Side Lobe Suppression (dB)

n/a

11

Front to Back Ratio (dB)

n/a

25

Beam Parallelity (BrM1●BrM2) (dB)

n/a

-

EIRP (Typical) (dBm)

n/a

1 × 66.5

Vertical Beamwidth (°)

26±2

26±2

Horizontal Beamwidth (°)

65±5

65±5

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Antenna Integrated Radio Unit Description

Product

Scenario: Hotspot

Beam LTE

Beam NR

Parameter

BrHS1(1), BrHS2(2)

BrHS1(1)

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

>11

>11

Front to Back Ratio (dB)

25

25

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

-

EIRP (Typical) (dBm)

2 × 63.5

1 × 66.5

(1) Broadcast Beam Hotspot 1 (2) Broadcast Beam Hotspot 2

Table 5

AIR 6419 Typical Antenna Performance Data for Broadcast Beams in Highrise Scenario

Product

AIR 6419 B40

AIR 6419 B41

AIR 6419 B42

AIR 6419 B77G

6

Scenario: Highrise

Beam LTE

Beam NR

Parameter

BrHR1(1), BrHR2(2)

BrHR1(1)

Vertical Beamwidth (°)

28.5±3

28.5±3

Horizontal Beamwidth (°)

22.5±2

22.5±2

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

14

14

Front to Back Ratio (dB)

−

−

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 67.5

1 × 71

Vertical Beamwidth (°)

30±3

30±3

Horizontal Beamwidth (°)

20±2

20±2

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±1

0±1

Vertical Side Lobe Suppression (dB)

12

12

Front to Back Ratio (dB)

−

−

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 67.5

1 × 72

Vertical Beamwidth (°)

27±3

27±3

Horizontal Beamwidth (°)

20±2

20±2

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±5

0±5

Vertical Side Lobe Suppression (dB)

11

11

Front to Back Ratio (dB)

−

−

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

n/a

EIRP (Typical) (dBm)

2 × 68.5

1 × 72

Vertical Beamwidth (°)

n/a

20±2

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Technical Data

Product

AIR 6419 B78Y

Scenario: Highrise

Beam LTE

Beam NR

Parameter

BrHR1(1), BrHR2(2)

BrHR1(1)

Horizontal Beamwidth (°)

n/a

27±3

Digital Downtilt (°)

n/a

Fixed 6

Vertical Beam Pointing Error (°)

n/a

≤2

Horizontal Beam Pointing (°)

n/a

0±1

Vertical Side Lobe Suppression (dB)

n/a

11

Horizontal Side Lobe Suppression (dB)

n/a

17

Front to Back Ratio (dB)

n/a

28

Beam Parallelity (BrM1●BrM2) (dB)

n/a

-

EIRP (Typical) (dBm)

n/a

1 × 71

Vertical Beamwidth (°)

26±3

26±3

Horizontal Beamwidth (°)

20±2

20±2

Digital Downtilt (°)

Fixed 6

Fixed 6

Vertical Beam Pointing Error (°)

≤1

≤1

Horizontal Beam Pointing (°)

0±1

0±1

Vertical Side Lobe Suppression (dB)

>11

>11

Horizontal Side Lobe Suppression (dB)

>14

>17

Front to Back Ratio (dB)

28

28

Beam Parallelity (BrM1●BrM2) (dB)

≤ –10

-

EIRP (Typical) (dBm)

2 × 68

1 × 71.5

(1) Broadcast Beam Highrise 1 (2) Broadcast Beam Highrise 2

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7

Antenna Integrated Radio Unit Description

2.4

Physical Characteristics W

H

D Ge23267A

Figure 1 AIR 6419 Dimensions

D

H

W Ge25393A

Figure 2 AIR 6419 B41 Dimensions

8

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Technical Data

Table 6

AIR 6419 Dimensions

Product

Height, H (mm)

Width, W (mm)

Depth, D (mm)

AIR 6419 B40 With (R-state < protrusions R1E) Without protrusions

929

506

208

852

506

160

876

506

203

852

506

160

AIR 6419 B42 With protrusions

796

408

186

Without protrusions

717

408

140

With protrusions

793

408

230

Without protrusions

717

408

184

With protrusions

796

408

201

Without protrusions

717

408

155

AIR 6419 B40 With (R-state ≥ protrusions R1E) Without AIR 6419 B41 protrusions

AIR 6419 B77G

AIR 6419 B78Y

Table 7

AIR 6419 Weight

Product

Weight (kg)(1)

AIR 6419 B40

29.5 kg

AIR 6419 B41

29.5 kg

AIR 6419 B42

20.0 kg

AIR 6419 B77G

29.5 kg

AIR 6419 B78Y

22.0 kg

(1) The weight is given with ±5% accuracy.

Table 8

AIR 6419 Color

Part

Color Code

Body

NCS S 1002-B

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9

Antenna Integrated Radio Unit Description

2.5

Operating Environment Table 9

AIR 6419 Normal Operating Environment Values

Condition

Value

Temperature

−40°C to +55°C

Solar radiation

≤ 1,120 W/m²

Relative humidity

2% to 100%

Absolute humidity

0.26 to 40 g/m³

(1)

(1) Depending on installation scenario, traffic load, and configuration, the product can, in the highest 10 °C temperature range, temporarily reduce the output power. This depends on the durations of the high ambient temperature.

2.6

Wind Load Table 10

AIR 6419 Maximum Wind Load at 42 m/s

Product

Front (N)(1)

Side (N)(1)

AIR 6419 B40

642

136

AIR 6419 B41

653

110

AIR 6419 B42

454

105

AIR 6419 B77G

420

147

AIR 6419 B78Y

461

121

(1) According to EN 1991-1-4 pole installed AIR.

2.7

Heat Dissipation AIR 6419 is convection cooled and designed for outdoor installation. Max heat dissipation is calculated using the following formula: Max Heat Dissipation = Max Power Consumption − Configured Output Power Heat dissipation can be calculated for different traffic loads using values from Power Consumption Data. For more information, see Power Consumption Calculations.

10

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Technical Data

2.8

Vibration AIR 6419 operates reliably during seismic activity as specified by test method IEC 60068-2-57 Ff. Table 11

AIR 6419 Seismic Vibration Activity

Characteristic

Value

Maximum level of RRS

50 m/s² within 2–5 Hz for DR=2%

Frequency range

1–35 Hz

Time history signal

Verteq II from earthquake standard ATIS 0600329.2014

AIR 6419 operates reliably during random vibration as specified by test method IEC 60068-2-64. Table 12

AIR 6419 Random Vibration Normal Operation

Characteristic

Value

ASD-level

0.3 m²/s³ on horizontal axes X and Y 0.2 m²/s³ on vertical axis Z

2.9

Frequency range

2–200 Hz

Time per test direction

30 minutes

Acoustic Noise AIR 6419 does not have active cooling components. It can emit low levels of acoustic noise when operating on low capacity. The sound pressure level when operating on low capacity is lower than 28 dBA at 1-meter distance for hemispherical distribution, and 25 dBA for spherical distribution.

2.10

Power Supply Characteristics This section describes the power supply requirements, power consumption, and circuit breaker recommendations for the AIR.

2.10.1

DC Power Supply Characteristics AIR 6419 is designed for DC-I (3-wire) power connections used on DC-I (3-wire) sites. For DC-C (2-wire) power solutions, a DC-C (2-wire) connector is used. The following is a list of the power supply requirements:

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Antenna Integrated Radio Unit Description

Nominal Voltage Operating Voltage Range Non-destructive Range

−48 V DC −36.0 to −58.5 V DC 0 to −60 V DC

Fuse and Circuit Breaker Recommendations The recommendations given in this section are based on peak power consumption, and they give no information on power consumption during normal operation. The recommended melting fuse type is am-gL-gG, according to IEC 60269-1. Circuit breakers must comply with at least Curve 3 tripping characteristics, according to IEC 60947-2. The AIR has a built-in Class 1 (Type 1) SPD to protect the equipment in case of lightning and network transients. The recommended fuse or circuit breaker rating is therefore dimensioned to not trip the fuse or circuit breaker in case of SPD operation. Table 13

AIR 6419 Fuse and Circuit Breaker Recommendations

Product

Output Power

Maximum Load Current at −36 V DC

Maximum Allowed Fuse Rating(1)

AIR 6419 B40

320 W

40 A

50 A

AIR 6419 B41

320 W

40 A

50 A

AIR 6419 B42

320 W

40 A

50 A

AIR 6419 B77G

320 W

40 A

50 A

AIR 6419 B78Y

320 W

40 A

50 A

(1) The maximum allowed fuse rating must (with a certain safety margin 10-20%) be larger than the maximum load current for reliable operation. However, it must not be larger than the next or nearest higher fuse or circuit breaker standard value in order to minimize the cable crosssection area and at the same time fully comply with relevant safety standards.

2.10.2

Power Consumption For information on power consumption, see Power Consumption Calculations and Power Consumption Data.

2.11

RF Electromagnetic Field Exposure For general information on RF EMF exposure, see Radio Frequency Electromagnetic Fields. The tables list the compliance boundaries (exclusion zones), outside of which the RF EMF exposure from AIR 6419 is below the limits specified by the ICNIRP, and the limits applicable in: — EU (1999/519/EC, 2013/35/EU, EN 50385) Table 14

12

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Technical Data

— USA (47 CFR 1.1310) Table 15 — USA (53 CFR 1.1310) Table 16 Information is provided for the theoretical maximum exposure condition and for the actual maximum exposure condition (see IEC 62232). The theoretical maximum exposure condition does not consider how the time-averaged power is distributed within the scan range of the product and is very conservative. The actual maximum exposure condition takes into account the effects of beam scanning on the time-averaged power that contributes to the RF exposure. A Power Reduction Factor (PRF) of 0.32 was used to represent realistic deployment scenarios (see IEC TR 62669). Note:

National regulations can prescribe requirements on the use of actual maximum exposure conditions for RF EMF compliance assessments.

Table 14 Dimensions of the Box-Shaped Compliance Boundary for General Public (GP) and Occupational (O) Exposure Applicable in the EU and Markets Employing the ICNIRP RF Exposure Limits Mode and Output Power

Dimensions of the Box-Shaped Compliance Boundary(1)(2) (m) Distance in Front of AIR

Width

Height

Distance Behind AIR

Prod uct

Standard

Maximu m Nominal Output Power from the AIR

IEC 62232 Installati on Class

Power Toleranc e

TDD DL Duty Cycle

Exposure Condition

GP

O

GP

O

GP

O

GP

O

AIR 6419 B40

LTE

320 W

E+

1.5 dB

75%

Theoretic al Maximu m

23.0

10.3

27.2

12.2

12.4

5.6

0

0

Actual Maximu m (PRF = 0.32)

13.9

6.3

15.8

7.1

7.3

3.3

0

0

Theoretic al Maximu m

25.7

11.5

31.0

13.9

14.0

6.3

0

0

Actual Maximu m (PRF = 0.32)

14.5

6.5

17.6

7.9

8.0

3.6

0

0

Theoretic al Maximu m

24.0

10.8

27.8

12.5

11.8

5.3

0

0

Actual Maximu m (PRF = 0.32)

14.5

6.5

16.1

7.2

7.0

3.2

0

0

Theoretic al Maximu m

26.9

12.0

31.8

14.2

13.4

6.0

0

0

AIR 6419 B40

AIR 6419 B41

AIR 6419 B41

NR

LTE(3)

NR

320 W

320 W

320 W

E+

E+

E+

1.5 dB

1.0 dB

1.0 dB

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75%

75%

75%

13

Antenna Integrated Radio Unit Description

Mode and Output Power

Prod uct

AIR 6419 B42

AIR 6419 B42

AIR 6419 B78Y

AIR 6419 B78Y

Standard

LTE

NR

Maximu m Nominal Output Power from the AIR

320 W

320 W

LTE

320 W

Actual Maximu m (PRF = 0.32)

15.5

NR

320 W

Dimensions of the Box-Shaped Compliance Boundary(1)(2) (m)

IEC 62232 Installati on Class

E+

E+

E+

E+

Power Toleranc e

1.0 dB

1.0 dB

1.0 dB

1.0 dB

TDD DL Duty Cycle

75%

75%

75%

75%

Distance in Front of AIR

Width

Height

Distance Behind AIR

Exposure Condition

GP

O

GP

O

GP

O

GP

O

Actual Maximu m (PRF = 0.32)

15.2

6.8

18.0

8.1

7.6

3.4

0

0

Theoretic al Maximu m

25.4

11.4

29.5

13.2

11.7

5.3

0

0

Actual Maximu m (PRF = 0.32)

15.2

6.8

17.1

7.7

6.9

3.1

0

0

Theoretic al Maximu m

28.4

12.7

33.7

15.1

13.2

5.9

0

0

Actual Maximu m (PRF = 0.32)

16.1

7.2

19.1

8.6

7.5

3.4

0

0

Theoretic al Maximu m

25.7

11.5

29.9

13.4

11.8

5.3

0

0

7.0

17.3

7.8

7.0

3.2

0

0

Theoretic al Maximu m

29.8

13.3

33.6

15.0

13.4

6.0

0

0

Actual Maximu m (PRF = 0.32)

16.9

7.6

19.0

8.5

7.6

3.4

0

0

(1) The compliance boundaries are determined for maximum output power with power tolerance and TDD downlink duty cycle included, and for theoretical maximum and actual maximum exposure conditions. (2) For LTE, the compliance boundaries are determined for 75% of the power allocated to traffic beams and 25% to the broadcast beam. For actual maximum power conditions, the PRF of 0.32 was applied only to the power fraction allocated to traffic beams. (3) For NR+LTE mixed mode, the results for NR apply.

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Technical Data

Table 15 Dimensions of the Box-Shaped Compliance Boundary for General Public (GP) and Occupational (O) Exposure Applicable in the USA and Markets Employing the FCC Exposure Limits Dimensions of the Box-Shaped Compliance Boundary(1)(2) (m)

Mode and Output Power

Distance in Front of AIR

Width

Height

Distance Behind AIR

Produ ct

Standard

Maximum Configure d Output Power from the AIR

IEC 62232 Installatio n Class

Power Tolerance

TDD DL Duty Cycle

GP

O

GP

O

GP

O

GP

O

AIR 6419 B41

LTE(3)

60 W

E+

1.0 dB

75%

10.4

4.7

12.1

5.4

5.2

2.3

0.2

0.2

80 W

E+

1.0 dB

75%

12.0

5.4

13.9

6.3

5.9

2.7

0.2

0.2

120 W

E+

1.0 dB

75%

14.7

6.6

17.1

7.7

7.3

3.3

0.2

0.2

160 W

E+

1.0 dB

75%

17.0

7.6

19.7

8.8

8.4

3.8

0.2

0.2

240 W

E+

1.0 dB

75%

20.8

9.3

24.1

10.8

10.3

4.6

0.2

0.2

320 W

E+

1.0 dB

75%

24.0

10.8

27.8

12.5

11.8

5.3

0.2

0.2

60 W

E+

1.0 dB

75%

11.7

5.2

13.8

6.2

5.8

2.6

0.2

0.2

80 W

E+

1.0 dB

75%

13.5

6.0

15.9

7.1

6.7

3.0

0.2

0.2

120 W

E+

1.0 dB

75%

16.5

7.4

19.5

8.7

8.2

3.7

0.2

0.2

160 W

E+

1.0 dB

75%

19.0

8.5

22.5

10.1

9.5

4.3

0.2

0.2

240 W

E+

1.0 dB

75%

23.3

10.4

27.5

12.3

11.6

5.2

0.2

0.2

320 W

E+

1.0 dB

75%

26.9

12.0

31.8

14.2

13.4

6.0

0.2

0.2

AIR 6419 B41

NR

(1) The compliance boundaries are determined for maximum output power with power tolerance and TDD downlink duty cycle included. (2) For LTE, the compliance boundaries are determined for 75% of the power allocated to traffic beams and 25% to the broadcast beam. (3) For NR+LTE mixed mode, the results for NR apply.

Table 16 Dimensions of the Box-Shaped Compliance Boundary for General Public (GP) and Occupational (O) Exposure Applicable in the USA and Markets Employing the FCC Exposure Limits Dimensions of the Box-Shaped Compliance Boundary(1) (m)

Mode and Output Power

Distance in Front of AIR

Width

Height

Distance Behind AIR

Produ ct

Standard

Maximum Configure d Output Power from the AIR

IEC 62232 Installatio n Class

Power Tolerance

TDD DL Duty Cycle

GP

O

GP

O

GP

O

GP

O

AIR 6419 B77G

NR

60 W

E+

1.5 dB

75%

13.4

6.0

16.0

7.2

6.3

2.8

0.2

0.2

80 W

E+

1.5 dB

75%

15.4

6.9

18.5

8.3

7.3

3.3

0.2

0.2

120 W

E+

1.5 dB

75%

18.9

8.5

22.6

10.1

8.9

4.0

0.2

0.2

160 W

E+

1.5 dB

75%

21.8

9.8

26.1

11.7

10.2

4.6

0.2

0.2

240 W

E+

1.5 dB

75%

26.7

12.0

32.0

14.3

12.5

5.6

0.2

0.2

320 W

E+

1.5 dB

75%

30.8

13.8

36.9

16.5

14.5

6.5

0.2

0.2

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Antenna Integrated Radio Unit Description

(1) The compliance boundaries are determined for maximum output power with power tolerance and TDD downlink duty cycle included.

2.12

Software For information on software dependencies, see Supported Radio Capabilities.

2.13

Radio Configurations For information about available radio configurations, see Radio Node Configurations.

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Hardware Architecture

3

Hardware Architecture

C

D

B

A

E Ge23270A

Figure 3 AIR 6419 Parts Table 17

AIR 6419 Parts

Position

Component

A

Radome

B

Cooling fins

C

Handles

D

L-shape brackets

E

Connection interfaces

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17

Antenna Integrated Radio Unit Description

A

B C

D Ge25180B

Figure 4 AIR 6419 B40 (R-state ≥ R1E), B41 Parts Table 18

18

AIR 6419 B40 (R-state ≥ R1E), B41 Parts

Position

Component

A

Radome

B

Cooling fins

C

L-shape brackets with integrated handles

D

Connection interfaces

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Installation Requirements

4

Installation Requirements AIR 6419 is designed for outdoor use, and it can be installed either on a pole, on a wall, on a mast, or on a tower. Pole clamps, brackets, mounting accessories and other installation material or equipment specified by Ericsson must be used and Ericsson installation instructions be complied with.

4.1

Outdoor Installation Environments to Avoid To ensure optimal operation, avoid the following: — Hot microclimates caused by, for example, heat radiated or reflected from dark, metallic or glass surfaces — Chimney mouths or ventilation system outlets Avoid radio interference by keeping the area in front of the antenna clear of the following: — Metal surfaces or objects such as ladders, cabinets, enclosures — Equipment generating electromagnetic fields, for example, electric motors in air conditioners or diesel generators

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19

Antenna Integrated Radio Unit Description

AIR

Directional beams

No interfering objects in front of the AIR! Ge13022C

Figure 5 Objects to Avoid in Front of AIR 6419

4.2 A

Installation Alternatives B

C

D

Ge23268B

Figure 6 AIR 6419 Installation Alternatives

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Installation Requirements

Table 19

AIR 6419 Installation Alternatives

Installation Method

Description

A

Pole installation (pole with circular cross section)

B

Pole installation (pole with square cross section)

C

Pole installation (pole with 90° angle cross section)

D

Wall installation

Tilt and swivel are supported depending on mounting bracket. For information on valid mounting brackets, see Site Installation Products Overview.

4.3

Space Requirements Front View

>0.1

AIR/Antenna

>0.1

AIR

>0.3

Y >0.3

Heat source

Unit of measurement: m

Ge16197B

Figure 7 Space Requirements for AIR 6419 Distance Y depends on the heat dissipation from the source below AIR 6419 and the surrounding temperature. The distance must be large enough so that the maximum operating temperature limit is not exceeded.

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21

Antenna Integrated Radio Unit Description

Table 20 Temperature Increase Due to Heat Source Below AIR 6419 at Different Distances Distance Y

Heat Dissipation from Source Below AIR 6419 350 W

500 W

950 W

1200 W

0.2 m

1°C

3°C

5°C

6°C

0.3 m

0°C

1°C

3°C

4°C

0.5 m

0°C

0°C

2°C

3°C

To ensure adequate airflow, do not enclose AIR 6419 in a box-like environment. AIR 6419 is installed with the cable connections facing down. Allow enough free space below AIR 6419 to ensure sufficient working space.

4.4

Painting Disclaimer Ericsson recommends to not paint the product as it can affect performance of the product. Ericsson applies limitations to the warranty and service contract if the product is painted. If the product is painted, the following commercial limitations apply: — Failure modes directly related to overheating because of painting are not valid for repair within the scope of the warranty or standard service contract. — Product failures related to paint contamination of components of the unit are not valid for repair within the scope of warranty or standard service contract. — When a painted unit is repaired, it might be restored to the standard color before being returned to the market. It is not possible to guarantee that the same unit is sent back to the same place. This is also valid for units repaired under a service contract. — For repairs within the warranty period or a standard service contract, the customer is charged the additional costs for replacing all painted parts of the unit or the complete unit. If adaptations are required, contact Ericsson for information.

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Interfaces

5

Interfaces A

G

H

I

B

C

D

E

F

J

1

2

K

Ge23272B

Figure 8 AIR 6419 Connection Interfaces, Optical Indicators, and Buttons Table 21

AIR 6419 Connection Interfaces

Position

Description

A

eCPRI 1

1

B

eCPRI 2

2

C

DIN 14 pin, following functions supported: —

RAE

—

EC light

—

External alarms

Marking

Connector Type

Illustration

LC (On SFP) with support for FullAXS

DIN 14 female connector

Note: If using more than one function, a Y-cable must be connected to the DIN 14

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23

Antenna Integrated Radio Unit Description

Position

Description connector for each added function.

D

TX Monitor

E

−48 V DC power supply

F

Grounding

Connector Type

Illustration

SMA female connector

−48 V

Power connector

2 × 6 mm dual lug

Table 22

AIR 6419 Optical Indicators

Position

Marking

Indicator Name

G

Fault

H

Operational

I

Maintenance

J Note:

1,

2

Interface

After the radio power is switched on, it takes 20 to 30 seconds before the slow flashing (0.5 Hz) starts. The operational indicator only flashes once during this period.

Table 23

24

Marking

AIR 6419 Button

Position

Function

Description

K

Site test button

Controls site test operation before radio is connected to a baseband unit. For more information, see Perform Basic Stand-alone Radio Installation Check. Basic Stand-alone Radio Installation Check is supported for AIR 6419 B77G from R2 onwards.

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Interfaces

5.1

Optical Cable Interfaces The optical cable interfaces provide connections to optical cables for traffic and timing signals between AIR 6419 and a Baseband unit. An SFP is used to connect the optical cable to AIR 6419. Note:

There are different SFP modules for different products.

Only use SFP modules approved and supplied by Ericsson. For recommended SFP modules, see SFP Module Selector Guide.

5.1.1

eCPRI Interface AIR 6419 sets up connection with Baseband through eCPRI interface, an up to 25.8 Gbps Ethernet port.

5.2

DIN 14-Pin Interface The DIN 14-pin interface supports the following functions: — RAE — EC light — External alarms

5.2.1

RAE RAE is used to determine if the AAS unit has moved during a thunder storm, earthquake, or similar. The RAE unit is mounted on top of the AAS and measures four different properties: — Position — Antenna Azimuth — Mechanical Tilt — Antenna Mounting Height For the measurements, except for altitude measurement, satellite positioning systems are used. It means that the unit is dependent of free line of sight to several satellites to be able to work.

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Antenna Integrated Radio Unit Description

5.2.2

EC Light The EC light function delivers communication signals and alarms between the optional PSU and AIR 6419.

5.2.3

External Alarms The external alarms function can be used to monitor alarms from sensors on external equipment, for example doors, lights, and others.

5.3

TX Monitor Interface (Optional) The TX monitor interface provides monitoring of output power and performance.

5.4

−48 V DC Power Supply Interface The −48 V DC power connection is made through a connector with a 3-wire (DCI) connection or a connector with a 2-wire (DC-C) connection. For power cable dimensioning, see Site Installation Products Overview. For determining which connector or junction box to use, see Table 24. Table 24

AIR 6419 −48 V DC Power Supply Connector or Junction Box

Cross-Sectional Area of Each Conductor (mm²)

Connector or Junction Box

10–16

Used with connector RNT 447 36/01 (3wire (DC-I)) or RNT 447 37/01 (2-wire (DC-C))

25

Used with junction box NTB 101 75/1

The power cable conductor has a wire for both the 0 V conductor and a wire for the −48 V DC conductor. All cables must be shielded. The shielding must be properly connected both to the power connector and to the grounding in the power supply equipment. If the shielding is not connected, the AIR 6419 overvoltage and lightning protection do not function properly.

5.5

Grounding Interface AIR 6419 must be grounded to protect it from overvoltage and lightning strikes.

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Interfaces

For more information about grounding principles, see Grounding Guidelines for RBS Sites.

5.6

Optical Indicators Optical indicators show the system status. For more information about the optical indicators, see Indicators, Buttons, and Switches.

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27

Antenna Integrated Radio Unit Description

6

Standards and Regulations This section presents a brief overview of standards, regulatory product approval, and declaration of conformity for the radio. Declaration of Conformity "Hereby, Ericsson AB, declares that this product is in compliance with the essential requirements and other relevant provisions of Directive 2014/53/EU and 2011/65/EU."

6.1

Regulatory Approval The Radio System complies with the following market requirements: — European Union (EU) market requirements, Radio Equipment Directive (RED) 2014/53/EU The apparatus may include radio Transceivers with support for frequency bands not allowed or not harmonized within the EU. — Products containing radio Equipment outside North America and in countries not recognizing the CE-mark may be labeled according to national requirements or standards.

6.1.1

Environmental Standards Compliance The product complies with the following environmental standard: Europe — Restriction of Hazardous Substances in Electrical and Electronic Equipment (RoHS) Directive (2011/65/EU) bands not allowed or not harmonized within the EU.

6.1.2

Safety Standards Compliance In accordance with market requirements, the product complies with the following product safety standards and directives: International — IEC 62368-1

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Standards and Regulations

Europe — EN 50385 — EN 62368-1 USA — UL 62368-1 — FCC CFR 47 Part 1.1310 Canada — CAN/CSA-C22.2 No. 62368-1 — Health Canada Safety Code 6 6.1.2.1

Outdoor Specific Requirements The product complies with the following outdoor specific requirements: International — IEC 60529 (IP65) — IEC 60950-22 Europe — EN 60529 (IP65) — EN 60950-22 USA — UL 50E — UL 60950-22 Canada — UL 50E — CAN/CSA-C22.2 No. 60950-22

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29

Antenna Integrated Radio Unit Description

6.1.3

EMC Standards Compliance The product complies with the following Electromagnetic Compatibility (EMC) standards: International — 3GPP TS37.114 Europe — ETSI EN 301 489-1 — ETSI EN 301 489-50 USA — FCC CFR 47 Part 15 B Canada — ICES-003

6.1.4

Radio Standards Compliance The product complies with the following radio standards: International — 3GPP TS37.145-1 — 3GPP TS37.145-2 Europe — ETSI EN 301 908-1 USA — FCC CFR 47 Part 2 — FCC CFR 47 Part 27 Canada — IC RSS-Gen

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Standards and Regulations

— IC RSS-192

6.1.5

Marking To show compliance with legal requirements, the product is marked with the following labels: Europe — CE mark — WEEE symbol USA — FCC CFR 47 Part 15 Compliance Statement: “This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: •

This device may not cause harmful interference.

•

This device must accept any interference received, including interference that may cause undesired operation.”

— cETLus — FCC ID Canada — ISED IC-003 Compliance statement: “CAN ICES-3 (B)/NMB-3(B)” — cETLus — ISED Certification Number and HVIN (IC ID)

6.2

Other Standards and Regulations The standards and regulations in this section are not regulatory approved.

6.2.1

Spare Parts The product adheres to the Ericsson Serviceability and Spare Part Strategy.

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31

Antenna Integrated Radio Unit Description

6.2.2

Surface Quality The surface quality of AIR 6419 is according to Ericsson standard class A5 for the radome, top, front, and side covers, and A6 for the heat sink.

6.2.3

Vandal Resistance Unauthorized access is not possible without damaging the tamper proof warranty seal.

6.2.4

Materials All Ericsson products fulfill the legal, market, and Ericsson requirements regarding the following: — Material declaration — Materials' fire resistance, components, wires, and cables — Recycling — Restricted and banned material use

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