LBI-39128

INSTALLATION

Procedure

The following steps involve equipment in the Site Controller cabinet, except as noted:

1.Mark the cables and wires going to the old PMU as follows:

Mark “Antennas 1-4” on the cable going to the DB- 15 connector on the back of old PMU marked “Antennas 1-4”.

Mark “Transmitters 1-9” on the cable going to the DB-37 connector on the back of the old PMU marked “Transmitters 1-9”.

Mark “Transmitters 10-18” on the cable going to the DB-37 connector on the back of the old PMU marked “Transmitters 10-18”.

Mark “Transmitters 19-20” on the cable going to the DB-25 connector on the back of the old PMU marked “Transmitters 19-20”.

Mark “RS-232” on the cable going to the DB-25 connector on the back of the old PMU marked “RS-232”.

Mark “+” on the wire going to the screw terminal marked “+”.

Mark “–” on the wire going to the screw terminal marked “–”.

2.Turn off the main 12V power supply for the cabinet.

3.Disconnect the cables and wires from the old PMU.

4.Replace the old PMU with the new PMU. There will be a half rack unit space (7/8 inch) both above and below the PMU.

Connect the five DB-25 connectors on the other end of the adapter cable marked “P5”, “P6”, “P7”, “P8”, and “P9” to Port 1 through Port 5 respectively on the back of the new PMU.

6.Connect the 188D6496P1 adapter cable as follows:

Connect the DB-15 connector on the adapter cable marked “P2” to the existing cable (disconnected from the old PMU) marked “Antennas 1-4”.

Connect the DB-25 connector on the adapter cable marked “P3” to Port 7 on the back of the new PMU.

7.Connect the existing cable (disconnected from the old PMU) marked “RS-232” to the right VDT Interface connector on the back of the new PMU.

8.Connect the existing wires (disconnected from the old PMU) marked “+” and “–” to the screw terminals on the back of the new PMU marked “+” and “–” respectively.

9.Double check the installation using the interconnection diagram shown in Figure 12.

Transmitters 1-9

P2

 

 

 

 

 

Transmitters 10-18

 

 

 

 

 

P3

 

 

 

 

 

Transmitters 19-20

 

 

 

 

 

P4

 

 

 

 

 

 

 

 

 

 

 

188D6451P1 Adapter Cable

 

 

 

 

 

188D6496P1 Adapter Cable

 

 

 

 

 

Antennas 1-4

P2

 

 

 

 

 

 

P3

P7

P6

P9

P5

 

P8

VDT Interfaces

PORT 8

PORT 7

PORT 6

PORT 5

 

 

PORT 4

PORT 3

PORT 2

PORT 1

 

POWER MONITOR UNIT

 

 

 

 

 

 

 

 

_

Programming

 

 

 

 

 

+

Terminal

 

 

 

 

 

 

 

 

 

 

 

Connection

 

 

 

 

 

 

 

 

 

 

 

 

RS-232

5.Connect the 188D6451P1 adapter cable as follows:

Connect the two DB-37 connectors on the adapter cable marked “P2” and “P3” to the existing cables (disconnected from the old PMU) marked “Transmitters 1-9” and “Transmitters 10-18” respectively.

Connect the single DB-25 connector on one end of the adapter cable marked “P4” to the existing cable (disconnected from the old PMU) marked “Transmitters 19-20”.

Figure 12 - Connections for Adaptation from Old PMU

10.Set the power switch on the back of the PMU to the “Off” position.

11.Turn on the main 12V power supply for the cabinet.

INITIAL POWER-UP

After the PMU equipment has been mounted and checked, you are ready for the initial power-up of the PMU.

1.Temporarily disconnect the data link cable to the Site Controller computer from the right-hand VDT Interface

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Ericsson LBI-39128 manual Initial POWER-UP

LBI-39128 specifications

Ericsson LBI-39128 is a comprehensive communication solution designed to meet the ever-evolving demands of modern telecommunications. It is renowned for its ability to enhance network performance while providing a robust framework for various communication technologies. This product primarily targets service providers, enabling them to maximize their operational efficiency and improve service delivery.

One of the key features of the LBI-39128 is its versatility in supporting multiple generation technologies, including 2G, 3G, LTE, and even 5G. This ensures that service providers can seamlessly integrate their existing infrastructure and gradually evolve towards more advanced network capabilities without the need for a complete overhaul. The product caters to a wide array of deployment scenarios, from urban environments with high user density to rural areas requiring expansive coverage.

In terms of network performance, the LBI-39128 excels with its advanced radio technologies. It employs Massive MIMO (Multiple Input Multiple Output) and beamforming techniques, which significantly enhance spectral efficiency and improve user experience. With multiple antennas transmitting and receiving signals simultaneously, users benefit from increased throughput and reduced latency, essential for applications such as video streaming and real-time communications.

Another critical characteristic of the Ericsson LBI-39128 is its focus on energy efficiency. The product integrates intelligent power management systems that optimize energy consumption, thereby reducing operational costs for service providers. This aligns with the growing emphasis on sustainable practices within the telecommunications industry.

Moreover, the LBI-39128 features advanced management and automation capabilities. Its network function virtualization (NFV) support enables operators to deploy virtualized network functions efficiently, allowing for dynamic scaling and resource allocation based on real-time demand. This agility is crucial for handling varying loads and enhancing the overall resilience of the network.

Security is also a primary consideration in the design of the LBI-39128. It incorporates robust encryption methods and secure access protocols to protect sensitive data and ensure the integrity of communication channels. This is particularly important in an age where cyber threats are becoming increasingly prevalent.

In summary, the Ericsson LBI-39128 is a state-of-the-art telecommunications solution that stands out due to its support for multiple technologies, advanced radio capabilities, energy efficiency, automated management, and robust security features. Its design reflects the needs of contemporary service providers, allowing them to build and sustain high-performance networks that meet the demands of future communications.