No.
- VHF+UHF RDU - - 700LTEF SISO RDU - Confidential & Proprietary 62/136
- 700LTEF MIMO RDU - Figure 4.34 – RDU Outer Look 2) AOR Power Supply Unit (AOR PSU) AOR PSU receives -48V of input. This unit is divided into DC/DC type to output +6V, +9V and +27V of DC power and AC/DC type to receive 110V of AC input and to output +6V, +9V and +27V of DC power. Upon your order, either of the two types should be decided. MS Connector, which uses ports to receive inputs, is designed to accept any of AC and DC. Only in this case, the input cable is different.
3) AOR System Interface Unit(SIU) SIU distributes power and signals to each module. 4.5.5 Rear of AOR 1) Functions Figure 4.35 – AOR Rear Look Item 1.
2. VHF/UHF & 700LTEF RX OUT 3. Power Port 4. VHF/UHF TX OUT 700LTEF MIMO ANT 5. VHF/UHF RX IN 700LTEF SISO ANT Terminal for transmit the signal of RX to existing ROU ROU Terminal for input either AC 110V or DC-48V as internal PSU type Terminal for radiate the signal of TX to TX Antenna To/From Antenna Terminal for receive the signal of RX from RX Antenna 6.External Port Port for communicate with existing ROU 7.
Section5 System Installation & Operation 5.1 BIU Installation 5.2 ODU Installation 5.3 ROU Installation 5.4 OEU Installation 5.5 System Operation and Alarm Status 5.
This chapter describes how to install each unit and optical cables, along with power cabling method. In detail, the chapter describes how to install shelves or enclosuers of each unit, Power Cabling method and Optic Cabling and RF Interface. Furthermore, by showing power consumption of modules to be installed in each unit, it presents Power Cabling budget in a simple way. Then, it describes the quantity of components of modules to be installed in each unit and expansion method. 5.1 BIU Installation 5.1.
Basically, the common part of BIU should have shelves and it should be equipped with MCDU to combine and divide TX/RX signals, MPSU to supply devices with power, MCPU to inquire and control state of each module and Power Cable to supply power from external rectifiers. In addition, MDBU can be inserted and removed to provide services for desired band (Optional). 5.1.2 BIU Power Cabling BIU has -48V of input power. This unit should connect DC cable with the Terminal Block seen at the rear of BIU.
Note that BIU does not operate if the "+" terminal and the "–" terminal of the -48V power are not inserted into the accurate polarity. When you connect -48V power with BIU, use the ON/OFF switch of MPSU located at the front of BIU to check the power. Power Switch LED Description Abnormal, Not supply Power -48Vdc ON Normal supply power -48Vdc O Normal Status DC ALM Failure of output Power ON I Normal Status DC ALM 5.1.
In/out RF Port No Unit naming Description TX 800PS RX 800PS Port #1 TX(851~869MHz) 1 800PS MDBU RX(806~824MHz) Single Band 800PS 800PS Port#2 TX(851~869MHz) RX(806~824MHz) 850C Port #3 850C TX(869~894MHz) RX(824~849MHz) 2 850C MDBU Single Band 850C Port#4 850C TX(869~894MHz) RX(824~849MHz) 1900P 1900P TX(1930~1995MHz) RX(1850~1915MHz) 1900P 1900P TX(1930~1995MHz) RX(1850~1915MHz) 1900P 1900P TX(1930~1995MHz) RX(1850~1915MHz) 1900P 1900P TX(1930~1995MHz) RX(1850~1915MHz) AWS-1
Paging Paging TX(929~932MHz) RX(896~902MHz) 900I TX(929~941MHz) 900I RX(896~902MHz) 700PS 700PS TX(764~776MHz) RX(794~806MHz) 700PS 700PS TX(764~776MHz) RX(794~806MHz) Port#3 850C TX(869~894MHz) 850C RX(824~849MHz) Port#4 850C TX(869~894MHz) 850C RX(824~849MHz) VHF VHF Tx(136~174MHz) Rx(136~174MHz) UHF UHF Tx(380~512MHz) Rx(380~512MHz) 700LTEC 700LTEC TX(746~756MHz) RX(777~787MHz) 700LTEC 700LTEC TX(746~756MHz) RX(777~787MHz) Port#3 850C TX(869~894MHz) 850C RX(824~849MH
700LTEF MIMO 700LTEF MIMO RX(698~716 MHz) Port#1 TX(728~757MHz) (777~787 MHz) 700LTEF MIMO 700LTEF MIMO Port#2 RX(698~716 MHz) TX(728~757MHz) (777~787 MHz) 700LTEF MIMO 11 Single Band MDBU 700LTEF MIMO 700LTEF MIMO RX(698~716 MHz) Port#3 TX(728~757MHz) (777~787 MHz) 700LTEF MIMO 700LTEF MIMO RX(698~716 MHz) Port#4 TX(728~757MHz) (777~787 MHz) At the rear of BIU, input and output ports are seen for each MDBU. The name of all the ports are silk printed as "#1, #2, #3 and #4.
Through spectrum, you need to check signals sent from BTS TX. If the signals exceed input range (-20dBm~+10dBm), you can connect an attenuator ahead of the input port to put the signals in the input range. BIU interface with Bi-Directional Amplifier Basically, BIU is in Simplexer type; when you use BDA, you need to separate BDA signals from TX and RX type. Using a duplexer or a circulator, you can separate TX/RX signals of an external device from each other. Figure 5.
Figure 5.3 – 800PS BDA Interface using Duplexer BIU interfaces with BDA in either of the methods above. In this case, you need to check TX input range as well. Given the TX input range (-20dBm~+10dBm/Total per port), make sure to see if the value is in the input range, using Spectrum Analyzer, when you connect input ports.
5.1.4 MDBU insertion MDBU is designed to let a MDBU be inserted into any slot. BIU can be equipped with a total of four MDBUs. If only one MDBU is inserted into a slot with the other slots reserved, you need to insert BLANK cards into the other slots. If you do not terminate input and output ports of MCDU, which combines TX signals and divides RX signals, it will cause loss and generation of spurious signals at the other party's band. Given this, make sure to insert MDBU BLANK into slots of MDBU.
level of TX input and RX output signals in current service without affecting main signals. TX MON is -20dB compared with TX Input power and RX MON is -20dB as well compared with RX Output power. 5.1.5 ODU Interface BIU supports up to four ODUs. At the rear of BIU, eight RF input and output ports for ODU and four power ports for power supply and communication are provided. At BIU, you can check installation information of ODU.
If ODU is not connected in the right order, related devices may fail to communicate with each other or the unit may read wrong information. Given this, you need to connect the unit with accurate RF Port and Signal Port in a corresponding number. For unused RF Ports for ODU expansion, make sure to terminate them using SMA Term. When you put ODU on the top of BIU, it is recommended to install the unit at least 1U apart from BIU. Heat from BIU climbes up to reach ODU. 5.1.
MDBU 800PS 12W MDBU 800PS+900I+Paging 20W MDBU 850C 12W MDBU 850C+700PS 19W MDBU 1900P 20W MDBU AWS-1 12W MDBU 850C+700LTEC 19W MDBU 700LTEF SISO 12W MDBU 700LTEF MIMO 22W MDBU 700LTEF+850C 20W MDBU BIU supplies power for ODU. Therefore, when you want to calculate total power consumption of BIU, you need to add power consumption of ODU to the total value. Power consumption of ODU is given in the later paragraph describing ODU. 5.
When you connect 2-column, 15-pin D-SUB Signal cable from BIU and install DOU, LED on the front panel is lit. Through this LED, you can check state values of LD and PD of DOU. 5.2.3 ODU Optic Cabling As optical module shelf, ODU makes electronic-optical conversion of TX signals and then makes optical-electronic conversion of RX signals. ODU can be equipped with up to two DOUs. One DOU supports four optical ports and one optical port can be connected with ROU.
The following figure shows installation diagram of ODU with two DOUs inserted in it. When you insert DOU into ODU, insert the unit into the left DOU1 slot first. Into unused slot, you need to insert BLANK UNIT in any case. 5.2.5 Consumption Power of ODU ODU gets power from BIU. One ODU can be equipped with up to two DOUs. Depending on how many DOUs are installed, power consumption varies.
5.3 5.3.1 ROU Installation ROU Enclosure installation ROU is designed to be water- and dirt-proof. The unit has the structure of One-Body enclosure. It satisfies water-proof and quake-proof standards equivalent of NEMA4. ROU can be mounted into either of a 19” Standard Rack or on a Wall. Basically, ROU has both of a Wall Mount Bracket and a Rack Mount Bracket. Depending on the use of the Rack Mount Bracket, the bracket can be removed.
Figure 5.6 – Dimension used to install ROU on the WALL ROU Wall Mount Installation Turn M12 Fixing Screws by half on the wall and fully fix the screw with a Wall Mount Bracket on it. For convenience, the Wall Mount Bracket has fixing holes to let you easily mount an enclosure. Turn the M5 Wrench Bolt by half at each side of the Heatsink of the enclosure.
Put the enclosure with the M5 Wrench Bolt fixed on the fixing groove and fix the M5 Wrench Bolts into the remaining fixing holes. In this case, you will use 12 M5 Wrench Bolts in total except bolts used for the fixing groove. ROU Rack Mount Installation Like other units, ROU is designed to be inserted into a rack. The unit occupies around 13U of space except cable connection.
ROU component ROU has the following components: No.
to supply required power. In addition, RDU can be inserted and removed to provide service for desired band (Optional). 5.3.2 ROU Power Cabling ROU supports both of DC-48V and AC120V of input power. As RPSU for DC-48 and RPSU for AC120V are separated from each other, you need to select one of them in case of purchase order. RPSU for DC -48V and RSPU for AC 120V have the same configuration and capacity while each of the units uses different input voltage from each other.
MC Connector Lug Naming RPSU Terminal naming Remark numbering AC DC AC DC A AC_H -48V AC-H -48V B AC_N GND AC-N IN_GND C GND DC NC FG FG Check if the connection is the same as one seen in the table above and make sure to turn the power ON. 5.3.3 Optical Cabling ROU makes optical-electronic conversion of TX signals from upper ODU and OEU and makes electronic- optical conversion of RX signals. ROU has one optical module in it.
Optical cables should be inserted into Optic Port outside of ROU. Using an optical slack devices in ROU, you need to coil around one or two roll of cables to be connected with the optical adaptor of ROPTIC. At this time, curvature of the optical cable should be at least 10Ø to prevent insertion loss from being increased. Through GUI, check if PD value of ROPTIC is in a tolerable range (+4~-1dBm). 5.3.
