Baicells BAI-SBS71010 Nova846 Outdoor 8x5W eNodeB User Guide

Nova846
Outdoor 8x5W eNodeB
Quick Guide

Product Overview

**Introduction

**

The Baicells Nova846 is an advanced dual-mode outdoor integrated eNodeB (eNB) product that operates in LTE Time Division Duplexing (TDD) mode. This 8x5W and is capable of operating in Carrier Aggregation (CA) mode or Dual Carrier (DC) / split mode. Combining a variety of technologies, the Nova846 provides wireless coverage solutions, which will offer users high-speed broadband wireless Internet access. It also can help operators improve outdoor coverage, enhance network capacity, eliminate blind spots and improve cell-edge rates.
In CA mode, contiguous or non-contiguous channels are aggregated to provide up to 40 MHz bandwidth. This essentially doubles the downlink capacity when the CA mode is used with all CAT6/7/15 user equipment. In DC mode, each carrier is treated as an independent cell, supporting 128+128 users, and each supporting 20 MHz bandwidth.  Using a Nova846 in DC mode simplifies and streamlines the deployment of split sectors.
In addition to having the option to operate Nova846 in either CA or DC mode, HaloB (an embedded MME option) comes as a default feature in the base software. Baicells’s patented HaloB solution migrates the necessary core network functions to the and.
The Nova846 can be widely used by telecom operators, broadband operators, enterprises, etc.

Features

• Standard LTE TDD Bands 41,48.
• Support 5MHz/10MHz/15MHz/20MHz operation bandwidth.
• Peak rate (up to): DL 440 Mbps with 4×4 MIMO Carrier Aggregation (CA) model, UL 28 (56) Mbps.
• 128+128 concurrent users, 256+256 RRC users.
• Support GPS synchronization.
• Supports Citizens Broadband Radio Service (CBRS).
• Embedded HaloB (“lite” EPC) solution.
• Lower power consumption, which reduces OPEX, can be powered easily by Baicells compact outdoor Smart-UPS EPB series.
• Plug-and-play with self-organizing network (SON) capabilities.
• LoT with all standard LTE Evolved Packet Core (EPC).
• GUI-based local and remote web management, cooperating with the BaiOMC NMS to support unified configuration, management, monitoring, and maintenance.
• Highly secured with equipment certification against potential intrusion risk.
• TR-069 network management interfaces support.
  • Security services to provide timely protection against potential security risks and illegal intrusion.
  • Integration as required, easy to install and deploy, accurate coverage, and improved network capacity.

Appearance

The appearance of Nova846 is shown in Figure 1-1.

The Nova846 interfaces are described in Table 1-1.

connected to the external transmission network, used for data backhaul.
ETH1| Ethernet interface 2 (SFP optical interface), connected to an external transmission network, used for data backhaul.
PWR| Power interface: -48V (-40.5V to 57V) DC
ANTO—ANT7| Connect to external antenna 0 to antenna 7, N-type connector.
CAL/GPS| CAL is used for antenna phase alignment.
GPS is used to connect to an external GPS antenna, an N-type connector.

The Nova846 interface indicators are described in Table 1-2.

I dentity

| C olor| Status|

D escription

---|---|---|---
RUN| Green| Steady On| Power on
OFF| No power supply
ALM| Red| OFF| No alarm
Steady On| The system exists alarms.
ACT| Green| Steady On| The device has been powered on.
Fast flash: 0.125s on,0.125s off| Data is transmitting.
Slow flash: 1s on,1s off| The cell has been activated.
ETH0| Green| Steady On| S1 link is up.
OFF| SFP module is out of place, Ethernet cable is out of place, power of the optical module is powered off, or S1 link is down.
ETH1| Green| Steady On| S1 link is up.
OFF| SFP module is out of place, Ethernet cable is out of place, power of the optical module is powered off, or S1 link is down.

Technical Specification

Hardware Specification

Item

|

Description

---|---
LTE Mode| TDD
RF Standard| 3GPP 38.104 / Category B
LTE Bands| 41, 48
Channel Bandwidth| 5MHz, 10MHz, 15MHz, 20MHz
Carrier Config.| Maximum 2 carriers
MAX Output Power| 37 dBm / channel x 8 channel
MIMO| DL 4×4
Receive Sensitivity| -102 dBm
Synchronization| GPS
Data Interface| 1 x optical SFP + 1 x electrical GE or 2 x optical SFPs
Dimension| 432mm (H) x 280mm (W) x 118mm (D)
Installation Type| Pole or wall mount
Antenna Port| 8T8R
Antenna| • External high-gain antenna, N-type connector
• External GPS antenna, N-type connector
 Power consumption| ≤ 300W
Power| +40.5V to 57 V DC, Nominal +54VDC
Weight| 11.0kgs
Basic report function| RSSI, VSWR, TSSI(transmission signal strength), temperature, etc.
Cooling Method| Natural convection cooling @ vertical installation
Noise Figure| Room temperature: <2.5
All temperature: <3.5
MTBF| ≥ 150000 hours
MTTR| ≤ 1 hour

NOTE: The test method of receiving sensitivity is proposed by the 3GPP TS 36.104, which is based on 5MHz bandwidth, FRC A1-3 in Annex A.1 (QPSK, R=1/3, 25RB) standard.
Global Part Numbers

2 carriers.

Software Specification

SA1: DL 320Mbps, UL 28 (56)Mbps
SA2: DL 440Mbps, UL 14 (28)Mbps
• 2x10MHz:
SA1: DL 160Mbps, UL 14 (28)Mbps
SA2: DL 220Mbps, UL 7 (14)Mbps
Single carrier| • 20 MHz:
SA1: DL 160Mbps, UL 28Mbps
SA2: DL 220Mbps, UL 14Mbps
• 10MHz:
SA1: DL 80Mbps, UL 14Mbps
SA2: DL 110Mbps, UL 7Mbps
User Capacity| 128+128 concurrent users
256+256 RRC users
QoS Control| 3GPP standard Quality of Service Class Identifier (QCI)
Modulation| UL: QPSK, 16QAM, 64QAM
DL: QPSK, 16QAM, 64QAM, 256QAM
Voice Solution| VoLTE, Circuit Switched Fallback (CSFB)
Traffic Offload| Local breakout
SON| Self-organizing network:
• Automatic setup
• Automatic Neighbor Relation (ANR)
• PCI confliction detection
RAN Sharing Halong| Multi-Operator Core Network (MOCN)
Network Mgmt| Supported
RAN Sharing Halong| TR-069
Maintenance| Support remote/local maintenance
Support online status management
Support performance statistics
Support failure management*
Support configuration management
Support local or remote software upgrading and loading
Support log
Support connectivity diagnosis
Support self-start and self-configuration

*NOTE: Future software version will release.

±20 KA

Regulatory Compliance

FCC Compliance
This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.
Any changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment.

This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates uses and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following  measures:

• Reorient or relocate the receiving antenna.
• Increase the separation between the equipment and receiver.
• Connect the equipment into an outlet on a circuit different from that to which the receiver is connected.
• Consult the dealer or an experienced radio/TV technician for help.

Warning:
This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with a minimum distance of 50cm between the radiator & your body.

Installation

Installation Material
In addition to industry-standard tools, you will need the materials described in Table 2-1 during the installation. When selecting an RF antenna, be sure to match the frequency range of the antenna with the eNB.

AWG14). And the length from the power adaptor’s DC end to the device must be shorter than 100 meters (~109 yards).
Power plug| The power plug connects to the electricity supply.
Antenna RF cable| 50-ohm feeder
Optical fiber| Single-mode optical fiber
Antenna| Omnidirectional, or directional antenna
Ground cable| The diameter of the grounding cable must be 10mm²  or greater.

Installation Tool

NOTE: Other accessories have been packed in the packing box.

Install GPS Antenna

Read the following GPS antenna installation requirements before installing it on the eNB.

• No major blocking from buildings in the vicinity. Make sure the space atop is at least 45 degrees unblocked by any buildings.
• Avoid installing the GPS antenna in the vicinity of any other transmitting and receiving devices, to avoid interference.
• The GPS antenna should be installed within 45 degrees to the lightning rod.

The GPS antenna system is assembled in manufacturing before packing. The only installation step is to fix the GPS mounting bracket on the eNB with the M4*14 screws  (Figure 2-1).

NOTE: The eNB may adopt different models of GPS antenna, so the GPS antenna may not the same as the above figure. But the installation steps that fix it on the eNB are the same.

Weatherproofing

To protect the connection points from weather and climate, clean each connection point before installing cold shrink tubes, per the following figure.

1. Insert the cable into the cold shrink tube.
2. Tighten the connector.
3. Push the cold shrink tube to the top joint, and pull out the strip.
4. Ensure the cold shrink tube is tightly fitted with the connection.

Install on Pole

Check to ensure the diameter of the pole is in the range of 1.6 inches to 3.9 inches (40mm to 100 mm). The position of the RRU on the pole should be at least 47 inches (120  cm) in height.
The brackets have been pre-assembled in manufacturing before packing. It includes two parts, one is pre-assembled on the back of the device. The other one is for pole mounting or wall mounting, as shown in Figure 2-2.

Following steps introduce how to fix the pre-assembled eNB on a pole.

1. Take apart two clamps from the assembled bracket.

2. Put the bracket against the pole and assemble two clamps back. Note that the sequence of flat washers, spring washers, and nuts keeps the same as the original.

3. Fasten the pole bracket to ensure the bracket is firmly fixed on the pole.

4. Hang the device (with bracket) on the pole bracket. Ensure the screw on the bottom of the bracket clip into the groove on the pole bracket, and then fasten the screw.

Install on Wall

Take apart the assembly bracket first, only remains the wall bracket, as shown in Figure 2-3.

Following steps introduce how to fix the pre-assembled eNB on a wall.

1. Put the wall bracket against the wall and mark two drilling locations with a marker pen.

2. Drill two holes at the marked locations and install expansion bolts.

3. Hang the wall bracket on expansion bolts, and fasten with flat washers, spring washers, and nuts.

4. Refer pole mount step to hang the device on the wall bracket.

Connect Cable

NOTE:

1. According to the requirements of the site, both DC and AC power supplies are provided to support different requirements of the installation site. If DC power is selected, the power cable connects to the DC power supply directly. If AC power is selected, the power cable must connect to the AC power supply through a DC-AC adaptor.
2. The antenna ports and CAL/GPS port must have waterproof protection.

Power On

Power on the eNB, and wait a few minutes while the eNB boots up. Per the previous figures, check that the LED indicators are lighting as expected.

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