FibeAir® 1500HP/RFU-HP Technical Description

Transcription

FibeAir® 1500HP/RFU-HP
Technical Description
Document Revision 13
March 2012
Copyright © 2012 by Ceragon Networks Ltd. All rights reserved.
Notice
This document contains information that is proprietary to Ceragon Networks Ltd. No part of this
publication may be reproduced, modified, or distributed without prior written authorization of
Ceragon Networks Ltd. This document is provided as is, without warranty of any kind.
Registered Trademarks
Ceragon Networks® is a registered trademark of Ceragon Networks Ltd. FibeAir® is a registered
trademark of Ceragon Networks Ltd. CeraView® is a registered trademark of Ceragon Networks
Ltd. Other names mentioned in this publication are owned by their respective holders.
Trademarks
CeraMap™, ConfigAir™, PolyView™, EncryptAir™, and CeraMon™ are trademarks of Ceragon
Networks Ltd. Other names mentioned in this publication are owned by their respective holders.
Statement of Conditions
The information contained in this document is subject to change without notice. Ceragon
Networks Ltd. shall not be liable for errors contained herein or for incidental or consequential
damage in connection with the furnishing, performance, or use of this document or equipment
supplied with it.
Open Source Statement
The Product may use open source software, among them O/S software released under the GPL or
GPL alike license ("GPL License"). Inasmuch that such software is being used, it is released under
the GPL License, accordingly. Some software might have changed. The complete list of the
software being used in this product including their respective license and the aforementioned
public available changes is accessible on http://www.gnu.org/licenses/.
Information to User
Any changes or modifications of equipment not expressly approved by the manufacturer could
void the user’s authority to operate the equipment and the warranty for such equipment.
Ceragon Proprietary and Confidential
Page 2 of 52
Table of Contents
1. About This Guide.............................................................................................. 5
2. Target Audience ............................................................................................... 5
3. 1500HP/RFU-HP General Description ............................................................. 6
3.1
3.1.1
3.1.2
3.1.3
3.1.4
1500HP/RFU-HP References and Standards................................................................ 7
ETCI References and Standards ................................................................................... 7
FCC References and Standards .................................................................................... 7
EMC ............................................................................................................................... 8
Level 3 NEBS Compliance ............................................................................................. 8
3.2
IDU Compatibility ........................................................................................................... 9
3.3
System Management Options ........................................................................................ 9
3.4
Functional Block Diagram and Concept of Operation .................................................. 10
3.5
1500HP/RFU-HP Comparison Table ........................................................................... 12
4. 1500HP/RFU-HP System Configurations ...................................................... 13
4.1
Split Mount and All indoor ............................................................................................ 13
4.2 Space Diversity ............................................................................................................ 14
4.2.1 IF Combining (IFC) Mechanism ................................................................................... 14
4.2.2 Baseband Switching (BBS) .......................................................................................... 15
5. Split Mount Configuration and Branching Network ..................................... 16
5.1
5.1.1
5.1.2
5.1.3
1500HP/RFU-HP OCBs ............................................................................................... 17
Old OCB ....................................................................................................................... 17
New OCB ..................................................................................................................... 19
New OCB Component Summary ................................................................................. 20
5.2
Split-Mount Branching Loss ......................................................................................... 21
5.3
Upgrade Procedure ...................................................................................................... 21
6. All Indoor Configurations and Branching Network ...................................... 23
6.1
6.1.1
6.1.2
6.1.3
6.1.4
6.1.5
6.1.6
6.1.7
6.1.8
RFU Subrack Components .......................................................................................... 25
Subrack ........................................................................................................................ 25
Indoor Circulator Block (ICB) ....................................................................................... 26
RF Filters ...................................................................................................................... 26
Indoor Combiner Circulator (ICC) ................................................................................ 27
Indoor Combiner Circulator Diversity (ICCD) ............................................................... 27
Patch Panel .................................................................................................................. 27
Fan Tray ....................................................................................................................... 28
Rigid Waveguides - T12, T13 and T14 ........................................................................ 28
6.2
All-Indoor Configuration Example ................................................................................ 29
6.3
All-Indoor Rack Types .................................................................................................. 30
6.4
Rack Type Examples ................................................................................................... 30
6.5
All-Indoor Branching Loss ............................................................................................ 33
Page 3 of 52
7. All Indoor Compact (Horizontal) .................................................................... 34
7.1
All-Indoor Compact (Horizontal) Placements Components ......................................... 36
7.2
Power Distribution Unit (PDU) ..................................................................................... 37
8. 1500HP/RFU-HP Detailed Specifications ...................................................... 39
8.1
General Specifications ................................................................................................. 39
8.2
Transmit Power ............................................................................................................ 40
8.3
Power Consumption ..................................................................................................... 40
8.4
Frequency Bands Coverage ........................................................................................ 41
8.5
Receiver Threshold (RSL) (dBm @ BER = 10-6) ........................................................ 42
8.6
Mechanical Specifications ............................................................................................ 45
8.7
1500HP/RFU-HP Waveguide Flanges......................................................................... 45
8.8
IDU Compatibility ......................................................................................................... 46
8.9
Environmental Specifications ....................................................................................... 46
8.10 RFU Models and Part Numbers ................................................................................... 47
8.11 OCB Part Numbers ...................................................................................................... 48
8.11.1 OCB Part Number Format............................................................................................ 48
8.12 Generic All-Indoor Configurations Part Numbers ........................................................ 49
Page 4 of 52
1.
About This Guide
This document describes the main features, components, and specifications of
the FibeAir 1500HP/RFU-HP system.
2.
Target Audience
This manual is intended for use by Ceragon customers, potential customers,
and business partners. The purpose of this manual is to provide basic
information about the FibeAir 1500HP/RFU-HP for use in system planning.
Page 5 of 52
3.
1500HP/RFU-HP General Description
The FibeAir 1500HP/RFU-HP is a high transmit power RFU designed for long
haul applications with multiple carrier traffic. Together with its unique
branching design, 1500HP/RFU-HP can chain up to five carriers per single
antenna port and 10 carriers for dual port, making it ideal for Trunk or Multi
Carrier applications. The 1500HP/RFU-HP can be installed in either indoor or
outdoor configurations.
The field-proven 1500HP/RFU-HP was designed to enable high quality
wireless communication in the most cost-effective manner. With tens of
thousands of units deployed worldwide, the 1500HP/RFU-HP serves mobile
operators enabling them to reach over longer distances while enabling the use
of smaller antennas. The RFU-HP also includes a power-saving feature (“green
mode”) that enables the microwave system to automatically detect when link
conditions allow it to use less power.
1500HP and RFU-HP 1RX support Space Diversity via Baseband Switching in
the IDU (BBS). 1500HP 2RX, supports Space Diversity through IF Combining
(IFC). Both types of Space Diversity are valid solutions to deal with the
presence of multipath.
Note:
1500 HP (11 GHz) 40 MHz bandwidth does not support IF
Combining. For this frequency, space diversity is only
available via BBS.
Page 6 of 52
3.1
1500HP/RFU-HP References and Standards
1500HP/RFU-HP is compliant with the standards and frequency plans listed
in this section, for worldwide operation.
3.1.1
ETCI References and Standards











ITU-T Recommendation G.703 (1991): "Physical/electrical characteristics
of hierarchical digital interfaces".

ITU-T Recommendation G.707 (1996): "Network node interface for the
synchronous digital hierarchy (SDH/ SONET)".
CEPT/ERC 14-01E “Radio-frequency channel arrangements for radio-relay
systems operating in the 6LGHz band”.

3.1.2
EN 300 234: “Transmission and Multiplexing (TM); Digital Radio Relay
Systems (DRRS); High capacity DRRS carrying 1xSTM-1 / OC-3 signals and
operating in frequency bands with about 30 MHz channel spacing and
alternated arrangements”.
EN 300 385: "Electromagnetic compatibility and Radio spectrum Matters
(ERM); Electro Magnetic Compatibility (EMC) standard for fixed radio
links and ancillary equipment".
ETS 300 019: "Equipment Engineering (EE); Environmental conditions
and environmental tests for telecommunications equipment".
ETS 300 132-2: "Equipment Engineering (EE); Power supply interface at
the input to telecommunications equipment; Part 2: Operated by direct
current (dc)".
ITU-R Recommendation F.1191: "Bandwidths and unwanted emissions of
digital radio-relay systems".
ITU-R Rec. F.383-6: "Radio-frequency channel arrangements for high
capacity radio-relay systems operating in the lower 6 GHz band.
ITU-R Rec. F.384-7: “Radio-frequency channel arrangements for medium
and high capacity analogue or digital radio-relay systems operating in the
upper 6HGHz band
ITU-R Rec. F.385-6: “Radio-frequency channel arrangements for radiorelay systems operating in the 7 GHz band
ITU-R Rec. F.386-6: “Radio-frequency channel arrangements for medium
and high capacity analogue or digital radio-relay systems operating in the
8 GHz band
ITU-R Rec. F.387-8: “Radio-frequency channel arrangements for radiorelay systems operating in the 11 GHz band
FCC References and Standards


FCC 101.147 [7] “Radio-frequency channel arrangements for radio-relay
systems operating in upper 6HGHz band
FCC 101.147 [6] “Radio-frequency channel arrangements for radio-relay
systems operating in the 11GHz band”.
Page 7 of 52
3.1.3
EMC

3.1.4
System EMC and ESD requirements comply with the conditions specified
in EN 300 385 [9], for class B.
Level 3 NEBS Compliance
The New OCB is compliant with NEBS GR-1089-CORE, GR-63-CORE standards.
The NEBS compliance is applicable just to configurations which use the New
OCB, for Split-Mount and All-Indoor horizontally mounted setups, as shown
below.
Page 8 of 52
3.2
IDU Compatibility
1500HP/RFU-HP is compatible with the following IDU modules:
 IP-10G R2 and R3
 IP-10E
 IP-10Q
 1500R
 3200T
Note:
3.3
IP-10 R1 is supported with 1500HP 2RX and 1RX only.
System Management Options
1500HP/RFU-HP is managed in every Ceragon management system. The type
of management available (PolyView NMS/Web-Based EMS/CLI) depends on
the IDU to which the RFU is connected.
Page 9 of 52
3.4
Functional Block Diagram and Concept of Operation
The RFU handles RF signal processing. The RFU encompasses the RF
transmitter and receiver with all their related functions.
The 1500HP/RFU-HP product line was designed to answer the need for a high
power RF module together with IF combining functionality and the ability to
concatenate several carriers with minimal RF branching loss.
This section briefly describes the basic block diagrams for the various types of
RFUs included in the 1500HP/RFU-HP product line.
Figure 1: 1500HP 2RX in 1+0 SD Configuration
TX Board
OCB
Antenna
main
VCO
350MHz
Controller and
peripherals
-48V
PSU
140MHz
PreAmp
TX
chain
TX
TX
PA
DC / CTRL
C
o
n
n
e
c
t
o
r
C
o
n
n
e
c
t
o
r
TCXO
RF LPBK
Quadplexer
FSK
IF
RX
RX
chain
combiner
LNA
Extention port
RX Main
RX
RX
chain
LNA
10M
RX Diversity
diplexer
XLO
XPIC SW
Antenna
Diversity
VCO
IF & controller Board
RX
Chassis
XPIC source
IDU
(Ntype conn.) sharing \ RSL ind.
(TNC conn.)
Figure 2: 1500HP 1RX in 1+0 SD Configuration
TX Board
OCB
Antenna
main
VCO
TX
350MHz
Controller and
peripherals
-48V
PSU
140MHz
TX
chain
TX
FMM
FLM
DC / CTRL
C
o
n
n
e
c
t
o
r
C
o
n
n
e
c
t
o
r
TXCO
RF LPBK
Quadplexer
FSK
IF
RX
RX
chain
LNA
RX Main
Extention port
10M
diplexer
XLO
XPIC SW
VCO
IF & controller Board
Chassis
RX Board
XPIC source
IDU
(Ntype conn.) sharing \ RSL ind.
(TNC conn.)
Page 10 of 52
Figure 3: RFU-HP 1RX in 1+0 SD Configuration
OCB
Antenna
main
VCO
TX
XPIC source
sharing \ RSL
ind.
(BMA conn.)
Quadplexer
FSK
-48V
TX
RFIC
IF
Controller and
peripherals
PSU section
C
o
n
n
e
c
t
o
r
C
o
n
n
e
c
t
o
r
TX
chain
PreAmp
PA
DC / CTRL
40M
RF LPBK
IDU
(BMA conn.)
350MHz
RX
RX
chain
RX
RFIC
LNA
Extention port
140MHz
40M
diplexer
XLO
XPIC SW
VCO
PSC
TRX
Chassis
XPIC source
sharing \ RSL ind.
(TNC conn.)
Each of these RFU types must be connected to an OCB (Outdoor Circulator
Block) which serves as both a narrow diplexer and a mediation device to
facilitate antenna connection. For a detailed explanation of the OCB, refer to
1500HP/RFU-HP OCBs on page 17.
Page 11 of 52
3.5
1500HP/RFU-HP Comparison Table
The following table summarizes the differences between the 1500HP 2RX and
1RX and the RFU-HP.
1500HP/RFU-HP Comparison Table
Feature
1500HP 2RX
1500HP 1RX
RFU-HP 1RX
Notes
Frequency Bands Support 6L,6H,7,8,11GHz 6L,6H,7,8,11GHz 6L,6H,7,8GHz
3.5MHz – 56 MHz
--
--
√
10 MHz – 30 MHz
√
√
√
40MHz
--
√**
√
** 11GHz only – supports 2440MHz channels only
Split-Mount
√
√
√
All are compatible with OCBs from
both generations
All-Indoor
√
√
√
All are compatible with ICBs
Space Diversity
BBS and IFC1
BBS
BBS
IFC - IF Combining
BBS - Base Band Switching
Frequency Diversity
√
√
√
1+0/2+0/1+1/2+2
√
√
√
N+1
√
√
√
N+0 ( N>2)
√
√
√
High Power
√
√
√
Direct Mount Antenna
--
--
--
Power Saving Mode
--
--
√
Only the RFU-HP has the same
power for split mount and all indoor
installation. Refer to RFU Models
and Part Numbers on page 47.
Power consumption changes with
TX power
Note that the main differences between the 1500HP 1RX and RFU-HP 1RX are:
 RFU-HP offers higher TX power for split mount
 The RFU-HP 1RX offers full support for 3.5M-56MHz channels.
 The RFU-HP 1RX supports the green-mode feature
Both systems are fully compatible with all OCB and ICB devices.
1
1500 HP (11 GHz ) 40 MHz bandwidth does not support IF Combining. For this frequency,
space diversity is only available via BBS.
Page 12 of 52
4.
1500HP/RFU-HP System Configurations
4.1
Split Mount and All indoor
The 1500HP/RFU-HP radios can be installed either in split mount or in all
indoor configurations.
The following configurations are applicable for Split-Mount or all indoor
installations:
 Unprotected N+0 - 1+0 to 10+0 – Data is transmitted through N
channels, without redundancy (protection)
 Hot Standby - 1+1 HSB, 2+2 HSB – Two RFUs use the same RF channel
connected via a coupler. One channel transmits (Active) and the other acts
as a backup (Standby). A 2+2 HSB configuration uses two RFUs which are
chained using two frequencies and connected via a coupler to the other
pair of RFUs.
 N+1 Frequency Diversity - N+1 (1+1 to 9+1) – Data is transmitted
through N channels and an additional (+1) frequency channel, which
protects the N channels. If failure or signal degradation occurs in one of the
N channels, the +1 channel carries the data of the affected N carrier.
Additional configurations, such as 14+2, can be achieved using two racks.
Notes:

Space Diversity can be used in each of the configurations.
When using BBS for SD (1500HP 1RX/RFU-HP), ACM is not supported.

When the 1500HP/RFU-HP is mounted in a Split-Mount configuration, up to five RFUs can be
chained on one pole mount (the total is ten RFUs for a dual pole antenna).
When the 1500HP/RFU-HP is installed in an All Indoor configuration, there
are several installation options:
 In ETSI rack – up to ten radio carriers per rack


In 19” open rack – up to five radio carriers per subrack
Compact assembly – up to two radio carriers in horizontal placement
(without a subrack)
Two types of branching options are available for all indoor configurations:

Using ICBs – Vertical assembly, up to 10 carriers per rack (five carriers
per subrack)

Using OCBs – Compact horizontal assembly, up to 2 carriers per subrack
Page 13 of 52
4.2
Space Diversity
In long distance wireless links, multipath phenomenon commonly exist,
whereby fading occurs over time, space, and frequency. The 1500HP RFU
provides two types of Space Diversity optimizations, which are ideal solutions
for the multipath phenomenon:
 IF Combining (IFC)
 BBS (Base Band Switching)
The RFU-HP supports BBS Space Diversity, but not IFC.
Space Diversity with Multiple RFUs
4.2.1
Space Diversity with Single RFU
IF Combining (IFC) Mechanism
FibeAir 1500HP includes an IF combining mechanism, which uses an
innovative digital optimization algorithm to combine the signals received from
both antennas in order to improve signal quality. When distortion occurs, it is
measured in both receiver paths, and a new combined signal is produced. This
can improve the system gain by up to 3 dB. IFC Space Diversity can be used
with single and multiple RFUs.
A delay calibration for the diversity waveguide is required and is performed
automatically via the NMS.
Each 1500HP has built-in IFC Space Diversity functionality, with one
transmitter and two receivers. The receivers receive two different signals
from two antennas, which are installed 10-20 meters apart.
There are two options for connecting the RFUs to the diversity antennas:

Waveguide to coaxial cable – Uses a waveguide adaptor (CPR type)
connected to an N-type coaxial cable. This is the default option.

Elliptical waveguide – Uses a waveguide connector (CPR type) with an
elliptical waveguide.
Page 14 of 52
4.2.2
Baseband Switching (BBS)
Both FibeAir 1500HP and FibeAir RFU-HP support BBS Space Diversity. In
this option, there are two RFUs instead of a single RFU with two receivers.
The actual BBS Space Diversity switching is performed in the IDU. The modem
switches to the other RF signal when interference occurs, and returns to the
main signal when the interference is gone. In this way, the system performs
optimum signal receiving by using the signal that provides the best
performance.
Note:
When using BBS for SD (1500HP 1RX/RFU-HP), ACM is not
supported
Page 15 of 52
5.
Split Mount Configuration and Branching
Network
For multiple carriers, up to five carriers can be cascaded and circulated
together to the antenna port.
Branching networks are the units which perform this function and route the
signals from the RFUs to the antenna. The branching network can contain
multiple OCBs or ICBs. When using a Split-Mount or All-Indoor compact
(horizontal) configuration, the OCB branching network is used. When using an
All-Indoor vertical configuration, the ICB branching network is used.
The main differences in branching concept between the OCB and the ICB
relate to how the signals are circulated.


OCB – The Tx and the Rx path circulate together to the main OCB port.
When chaining multiple OCBs, each Tx signal is chained to the OCB Rx
signal and so on (uses S-bend section). For more details, refer to
1500HP/RFU-HP OCBs on page 17.
ICB – All the Tx signals are chained together to one Tx port (at the ICC) and
all the Rx signals are chained together to one Rx port (at the ICC). The ICC
circulates all the Tx and the Rx signals to one antenna port. For more
information, refer to Indoor Circulator Block (ICB) on page 26.
All-Indoor Vertical Branching
Split-Mount Branching and All-Indoor Compact
Page 16 of 52
5.1
1500HP/RFU-HP OCBs
The OCB (Outdoor Circulator Block) has the following main purposes:
 Hosts the circulators and the attached filters.
 Routes the RF signal in the correct direction, through the filters and
circulators.
 Enables RFU connection to the Main and Diversity antennas.
FibeAir 1500HP and RFU-HP supports two types of OCBs:
 OCB (Older Type)

New OCB
Old OCB
5.1.1
New OCB
Old OCB
The Older Type OCB has two types, Type 1 and Type 2. The difference
between the two types is the circulator direction. Depending on the
configuration, OCB Type 1 or Type2 is used together with waveguide shorts,
loads, U Bends, or couplers.
Each OCB has four waveguide access points: two in the front, and two at the
rear. The diversity access point is optional.
If the system is not configured for diversity, all the relevant access points on
the OCB must be terminated using waveguide shorts.
The two OCB types (with and without IFC Space Diversity) have different part
numbers.
Page 17 of 52
The following block diagrams show the difference between the two OCBs and
the additional Diversity Circ block which is added in some diversity
configurations.
Old OCB – Type 1
Old OCB – Type 1 and Type 2 Description
Page 18 of 52
5.1.2
New OCB
The new OCB is optimized for configurations that do not use IFC Space
Diversity. To support IFC Space Diversity, a diversity block is added.
The new OCB has only one type, and can be connected to an antenna via a
flexible waveguide.
The new OCB connection is at the rear of the OCB. It includes proprietary
accessories (different than those used for the older OCB).
Each OCB has three waveguide access points: The In/Out port is located at the
rear of the OCB.
The OCB ports include:
 Tx port


Rx Port
Diversity port
If the system is not configured for diversity, all the relevant access points on
the OCB must be terminated using waveguide shorts. Unused Rx ports are
terminated with a 50 ohm termination. New OCB and DCB Block Diagram
New OCB components include the following:
RF Filters
RF Filters are used for specific frequency channels and Tx/Rx separation. The
filters are attached to the OCB, and each RFU contains one Rx and one Tx filter.
In an IFC Space Diversity configuration, each RFU contains two Rx filters
(which combine the IF signals) and one Tx filter. The filters can be replaced
without removing the OCB.
Page 19 of 52
DCB (Diversity Circulator Block)
THE DCB is an external block which is added in IFC Space Diversity
configurations. The DCB is connected to the diversity port and can chain two
OCBs.
Coupler Kit
The coupler kit is used for 1+1 Hot Standby (HSB) configurations.
U Bend
The U Bend connects the chained DCB (Diversity Circulator Block) in N+1/N+0
configurations.
S Bend
The S Bend connects the chained OCB (Outdoor Circulator Block) in N+1 /N+ 0
configurations.
Pole Mount Kit
The Pole Mount Kit can fasten up to five OCBs and the RFUs to the pole. The kit
enables fast and easy pole mount installation.
5.1.3
New OCB Component Summary
New OCB Component Summary
Component Name Marketing Model
Marketing Description
DCB
DCBf
DCB Diversity Block f GHz kit
CPLR
OCB-CPLR-f
OCB Coupler f GHz
CPLR Sym
OCB-CPLR_SYM-f OCB symmetrical Coupler fGHz
U Bend
DCB-UBend
DCB Ubend connection f GHz
S Bend
OCB-SBend
OCB SBend connection f GHz
Pole Mount
OCB-Pole Mount
OCB-Pole Mount
Note:
f= 6L, 6H, 7, 8, 11 GHz
Picture
Page 20 of 52
5.2
Split-Mount Branching Loss
When designing a link budget calculation, the branching loss (dB) should be
considered as per specific configuration. This section contains tables that list
the branching loss for the following Split-Mount configurations.
Interfaces
1+0
1+1 FD/ 2+0
2+1
3+0
3+1
4+0
4+1
5+0
5+1
6+0
CCDP with DP
Antenna
0 (1c)
0 (1c)
0.5 (2c)
0.5 (2c)
1.0 (3c)
1.0 (3c) 1.5 (4c) 1.5 (4c) 2 (5c)
2 (6c)
0.5 (2c)
1.0 (3c)
1.5 (4c)
2.0 (5c)
NA
NA
SP Non-adjacent
0 (1c)
Channels
6+1
7+0
NA
7+1
8+0
NA
8+1
9+0
NA
Notes:
 (c) – Radio Carrier



CCDP – Co-channel dual polarization
SP – Single pole antenna
DP – Dual pole antenna
In addition, the following losses will be added when using these items:
5.3
Item
Where to Use
Loss (dB)
Flex WG
All configurations
0.5
15m Coax cable
Diversity path 6-8/11 GHz
5/6.5
Symmetrical Coupler
Adjacent channel configuration.
3.5
Asymmetrical coupler
1+1 HSB configurations
Main: 1.6
Coupled: 6.5
Upgrade Procedure
The following components need to be added when upgrading from a 1+0 to an
N+1 Split-Mount configuration:


• OCBs
• RFUs


• IDU/IDMs
• Flexible waveguides
When adding RF channels or carriers, RFUs and OCBs with specific filters need
to be added as well.
The OCBs are chained together using couplers (for the same frequency) or
U bends/S bends (for different frequencies), in accordance with the specific
configuration.
Open ports on the OCBs are terminated with 50 ohm terminations.
Page 21 of 52
9+1
10+0
Detailed upgrade procedure documents are available for specific
configurations.
Please note that legacy OCBs can be upgraded and cascaded with the new OCB.
Please contact your Ceragon representative for details.
Page 22 of 52
6.
All Indoor Configurations and Branching
Network
All-Indoor configurations are when all the equipment is installed indoors
(room, shelter) and an elliptical waveguide connects the radio output port
from the room to the antenna.
A basic block diagram for a trunk system, including the main blocks, is shown
in the following figure. The block diagram includes marked interface points
which shall serve as reference points for several technical parameters used in
this document.
Block Diagram of Trunk System
All-Indoor System with Five IP-10 Carriers
Page 23 of 52
All-Indoor System with Ten IP-10 Carriers
The branching concept (as described in Split Mount Configuration and
Branching Network on page 16) is similar to All-Indoor application.
When using All-Indoor configurations, there are two types of branching
implementations:
 Using ICBs – Vertical assembly, up to 10 carriers per rack (five carriers
per subrack).
 Using NEW OCBs – Compact horizontal assembly, up to two carriers per
subrack.
All-Indoor Installations
Page 24 of 52
6.1
RFU Subrack Components
Subrack for ETSI Rack
6.1.1
Subrack
The subrack hosts all the RFU components and connections, as shown in the
previous figure.
The subrack includes up to five RFUs per subrack (each RFU connects to an
ICB).
RFU with Branching
Page 25 of 52
6.1.2
Indoor Circulator Block (ICB)
Each RFU is connected to one ICB, and several ICBs are chained to each other.
The chained ICBs carry different RF channels and are connected to a single
ICC, which sums the RF signals.
The main ICB functions include:


Hosts the circulators and filters.
Routes the RF signals in the correct direction, via the filters and
circulators.
The ICB is a modular standalone unit. When system expansion is necessary,
additional ICBs are added and chained with the existing ICBs.
The branching chain to neighbor ICB goes through the holes at the side. A long
screw connects the ICBs to each other and the last ICB at the chain is
terminated with a 50ohm termination, as shown below.
Note:
The diversity port does not need to be terminated if the
diversity filter is not attached to the ICB.
ICB Branching Chain
6.1.3
RF Filters
The RF Filters are used for specific frequency channels and Tx/Rx separation.
The filters are attached to the ICB, and each RFU contains one Rx and one Tx
filter.
In an IFC Space Diversity configuration, each RFU contains two Rx filters to
combine the IF signals, along with one Tx filter.
Page 26 of 52
6.1.4
Indoor Combiner Circulator (ICC)
The ICC does not perform space diversity ICB summing (single output port).
ICC
The ICC sums the Rx and Tx signals and combines the N channels to the output
ports (one or two, in accordance with the configuration).
6.1.5
Indoor Combiner Circulator Diversity (ICCD)
The ICCD performs space diversity ICB summing (two output ports).
ICCD
6.1.6
Patch Panel
The ICB’s IF and XPIC cables are connected to the patch panel. The IDU’s IF
cables are connected to the specific RFU location. An XPIC cable is used
between two RFUs which are using the same Tx and Rx filters with different
polarizations (V and H).
Page 27 of 52
6.1.7
Fan Tray
The fan tray contains eight controlled and monitored fans, which cool the RFU
heat dissipations. The fan tray is a tray which is part of ETSI rack (as shown
above), while when using a 19” frame rack a fan tray is a separate unit which
must be assembled separately (shown below).
Fan Tray in 19” Frame Rack
6.1.8
Rigid Waveguides - T12, T13 and T14
Rigid waveguide sections are assembled in the rack to connect the ICC/ICCD
from the bottom to the top of the rack (C’). The specific Rigid WG sections to
be used depend on the configuration.
T12 Rigid Waveguide
T13 Rigid Waveguide
Page 28 of 52
6.2
All-Indoor Configuration Example
In this configuration, three ICBs are chained together and connected to a
vertical ICC, and two ICBs are chained together and connected to a horizontal
ICC polarization.
The RF components include:
 Five RFUs
 Five ICBs
 Two ICCs
4+1 XPIC Assembly Configuration
Additional Assembly Configuration Examples
Page 29 of 52
6.3
All-Indoor Rack Types
Three types of racks can be used in an all-indoor configuration:


19” lab rack ( open frame )
19” rack

ETSI rack
The 19” rack is not commonly used in Ceragon configurations.
The 19” lab rack (open frame) contains a subrack that is preassembled at the
factory and then shipped. The customer can also use an existing rack and the
subrack is installed separately at the site.
6.4
Rack Type Examples
Lab Rack (Open Frame) Examples
Page 30 of 52
19” Rack Example
ETSI Rack Example
Page 31 of 52
When a configuration includes more than ten carriers, two racks are
assembled and connected.
Configuration with More than Ten Carriers – Two Connected Racks
Page 32 of 52
6.5
All-Indoor Branching Loss
ICC has a 0 dB loss, since the RFU is calibrated to Pmax, together with the filter
and 1+0 branching loss. The following table presents the branching loss per
configuration and the Elliptical wave guide (WG) losses per meter which will
be add for each installation (dependant on the WG length).
Configuration
Interfaces
WG losses per 100m
Symmetrical Coupler
All-Indoor
CCDP with DP antenna
SP Non adjacent channels
Upgrade Ready
Configuration
1+0
Symmetrical Coupler
All-Indoor
SP Non adjacent channels
Upgrade Ready
2+1
3+0
3+1
4+0
4+1
5+0
6L
4
6H
4.5
7/8GHz
6
11GHz
10
Added to adjacent
channel configuration
3
Tx and Rx
0.3 (1c)
0.3 (1c)
0.7 (2c)
0.7 (2c)
1.1 (3c)
Diversity RX
0.2 (1c)
0.2 (1c)
0.6 (2c)
0.6 (2c)
1.0 (3c)
Tx and Rx
0.3 (1c)
0.7 (2c)
1.1 (3c)
1.5 (4c)
1.9 (5c)
Diversity RX
0.2 (1c)
0.6 (2c)
1.0 (3c)
1.4 (4c)
1.8 (5c)
Tx and Rx
0.3 (1c)
0.7 (1c)
1.1 (2c)
1.1 (2c)
1.5 (3c)
Diversity RX
0.2 (1c)
0.6 (1c)
1.0 (2c)
1.0 (2c)
1.4 (3c)
5+1
6+0
6+1
7+0
7+1
8+0
8+1
9+0
9+1
10+0
Interfaces
WG losses per 100m
1+1
FD
2+0
6L
4
6H
4.5
7/8GHz
6
11GHz
10
Added to adjacent
channel configuration
3
Tx and Rx
1.5 (3c)
1.9 (4c)
1.9 (4c)
2.3 (5c)
2.3 (6c)
Diversity RX
1.4 (3c)
1.8 (4c)
1.8 (4c)
2.2 (5c)
2.2 (6c)
NA
NA
NA
NA
NA
Tx and Rx
1.5 (3c)
1.9 (4c)
1.9 (4c)
2.3 (5c)
2.3 (6c)
Diversity RX
1.4 (3c)
1.8 (4c)
1.8 (4c)
2.2 (5c)
2.2 (6c)
Tx and Rx
Diversity RX
Page 33 of 52
7.
All Indoor Compact (Horizontal)
For minimal rack space usage, an All-Indoor configuration can be installed in
horizontal position using the new OCB in a 19” rack or ETSI open rack/ frame
rack. The New OCB is compliant with NEBS GR-1089-CORE, GR-63-CORE
standards.
Note:
This installation type and configuration does not require a
fan tray.
This installation type is compatible with the following RFUs PN:
Non Space Diversity All-Indoor
 15HPA-1R-RFU-f
 15HPA-2R-RFU-f
 15HPA-1R-RFU-11w
1500HP RFU All-Indoor 1Rx RF Unit
1500HP RFU All-Indoor Space Diversity
Page 34 of 52
1500HP RFU All-Indoor 1Rx RF Unit, 11G 40MHz
Main Configurations




1+0
1+0 East West
1+1
1+1 East West
1+1 HSB Compact Front View
1+1 HSB Compact Rear View
Page 35 of 52
7.1
All-Indoor Compact (Horizontal) Placements
Components
The following table lists the components for All-Indoor compact placements:
All-Indoor Compact Placement Components
Component Name Marketing Model
Marketing Description
DCB
DCBf
DCB Diversity Block f GHz kit
CPLR
OCB-CPLR-f
OCB Coupler f GHz
SBend
OCB-SBend
OCB SBend Connection f GHz
Rack Adapter
OCB 19” Rack Adapt
OCB-Pole Mount
Rack Adapter
OCB ETSI Rack Adapt
OCB-Pole Mount
Note:
Picture
f= 6L, 6H, 7, 8, 11 GHz
Page 36 of 52
7.2
Power Distribution Unit (PDU)
The PDU distributes the power supply (-48V) from the main power input to
the relevant IDU. The PDU is preassembled and wired in an ETSI rack and is
provided separately, when required, for a 19” lab rack. When ordering a 19”
configuration, there are two rack assembly options:
 19” lab rack provided separately
 19” lab rack provided by the customer
For both options, a PDU for 19” can be provided upon request.
There are two types of PDU. The default PDU which has been assembled with
each ETSI rack contains:
 Two main switches – one for each five IDU carriers
 Two FAN tray switches
1A. The default PDU which is assembled with the ETSI rack has a special
addition of a plastic cover.
For special cases, when PDU protection is required, a PDU with plastic
protection cover can be provided.
The PN for this PDU with protection cover is: 32T-PDU_CVR.
Page 37 of 52
A PDU which distributes 10 x DC signals, the PDU type can be preassembled
with an ETSI Rack and needs to be specially ordered because it is not the
default PDU.
PDU with 10 Switches PN: 32T-PDU10
Page 38 of 52
8.
1500HP/RFU-HP Detailed Specifications
8.1
General Specifications
Available Frequency
Bands
1500HP 2RX: 6-11GHz
1500HP 1RX: 6-11GHz
RFU-HP: 6-8GHz
Supported Channel
BW
1500HP 2RX (6-11GHz): 10-30MHz
1500HP 1RX (6-11GHz): 10-30MHz
1500HP 1RX (11GHz wide): 24-40MHz
RFU-HP 1RX (6-8GHz): 3.5-56MHz
Diversity

1500HP 2RX – IFC

1500HP 1RX, RFU-HP 1RX – BB Swtiching
Supported
Modulations
4-256QAM
System
Configurations
Non-Protected (1+0), Protected (1+1), Space Diversity, 2+0/2+2 XPIC,
N+0, N+1
Installation Types
Split mount – remote mount, all indoor (No direct mount)
Tx Range
(Manual/ATPC)
Up to 20dB dynamic range
Frequency Stability
±4 ppm2
Frequency Source
Synthesizer
RF Channel Selection Via EMS/NMS
2
Over temperature.
Page 39 of 52
8.2
8.3
Transmit Power
1500HP Split-Mount
1500HP All-Indoor
RFU-HP-1R
Modulation
6-8 GHz
11 GHz
6-8 GHz
11 GHz
6-8 GHz
QPSK
30
27
33
30
33
8 PSK
30
27
33
30
33
16 QAM
30
27
33
30
33
32 QAM
30
26
33
29
33
64 QAM
29
26
32
29
32
128 QAM
29
26
32
29
31
256 QAM
27
24
30
27
30
Power Consumption
1500HP

Split-Mount (29dBm): 80W

All indoor (32dBm) : 100W
RFU-HP Power mode
TX Power
Range [dBm]
High
33-26
77
77
Medium
25-20
48
53
Low
19-11
34
34
Mute
NA
20
20
6L&H GHz
[Watt]
7&8GHz
[Watt]
Page 40 of 52
8.4
Frequency Bands Coverage
RFU Type
1500HP/RFU-HP
1500HP

Frequency
Band
Frequency Range [GHz]
L6 GHz
5.85-6.45
U6 GHz
6.4-7.1
7GHz
7.110 to 7.750
8 GHz
7.725 to 8.275
11 GHz
10.7 to 11.7
Specific frequency channelization is available as per customer requirement.
Page 41 of 52
8.5
Receiver Threshold (RSL) (dBm @ BER = 10-6)
Modulation Channel spacing
1500HP & IP-10G
RFU-HP & IP-10G
6-11GHz
6G
7-8G
-90.5
-91.5
-91.0
8 PSK
-87.4
-88.4
-87.9
16 QAM
-85.4
-86.4
-85.9
32 QAM
-82.8
-83.8
-83.3
64 QAM
-81.3
-82.3
-81.8
128 QAM
-79.0
-80.0
-79.5
256 QAM
-75.8
-76.8
-76.3
256 QAM
-72.3
-73.3
-72.8
-92.3
-93.3
-92.8
8 PSK
-88.6
-89.6
-89.1
16 QAM
-84.0
-85.0
-84.5
32 QAM
-80.5
-81.5
-81.0
64 QAM
-78.6
-79.6
-79.1
128 QAM
-76.3
-77.3
-76.8
256 QAM
-74.3
-75.3
-74.8
256 QAM
-70.7
-71.7
-71.2
-89.3
-90.3
-89.8
8 PSK
-85.5
-86.5
-86.0
16 QAM
-82.1
-83.1
-82.6
32 QAM
-80.5
-81.5
-81.0
64 QAM
-79.1
-80.1
-79.6
128 QAM
-76.1
-77.1
-76.6
256 QAM
-73.1
-74.1
-73.6
256 QAM
-70.8
-71.8
-71.3
QPSK
QPSK
QPSK
7MHz
10MHz
14MHz
Occupied
BW 99%
6.5MHz
9MHz
12.5MHz
Page 42 of 52
Occupied
BW 99%
1500HP & IP-10G
RFU-HP & IP-10G
QPSK
18 MHz
-88.9
-89.9
-89.4
8 PSK
-83.7
-84.7
-84.2
16 QAM
-81.4
-82.4
-81.9
32 QAM
-78.7
-79.7
-79.2
64 QAM
-76.1
-77.1
-76.6
128 QAM
-73.6
-74.6
-74.1
256 QAM
-70.6
-71.6
-71.1
256 QAM
-67.7
-68.7
-68.2
-88.1
-89.1
-88.6
8 PSK
-84.0
-85.0
-84.5
16 QAM
-81.7
-82.7
-82.2
32 QAM
-77.0
-78.0
-77.5
64 QAM
-75.0
-76.0
-75.5
128 QAM
-70.6
-71.6
-71.1
256 QAM
-70.0
-71.0
-70.5
256 QAM
-67.0
-68.0
-67.5
-87.8
-88.8
-88.3
8 PSK
-83.0
-84.0
-83.5
16 QAM
-79.1
-80.1
-79.6
32 QAM
-74.6
-75.6
-75.1
64 QAM
-73.0
-74.0
-73.5
128 QAM
-70.8
-71.8
-71.3
256 QAM
-68.7
-69.7
-69.2
256 QAM
-64.6
-65.6
-65.1
NA
-86.9
-86.4
8 PSK
NA
-81.4
-80.9
16 QAM
NA
-78.9
-78.4
32 QAM
NA
-75.1
-74.6
64 QAM
NA
-71.9
-71.4
128 QAM
NA
-70.7
-70.2
256 QAM
NA
-68.4
-67.9
256 QAM
NA
-65.8
-65.3
QPSK
QPSK
QPSK
20MHz(FCC)
28MHz
30MHz(FCC)
40MHz (ETSI)
26MHz
27.5 MHz
36.5MHz
Page 43 of 52
Occupied
BW 99%
1500HP & IP-10G
RFU-HP & IP-10G
QPSK
36.5MHz
NA
-86.9
-86.4
8 PSK
NA
-81.4
-80.9
16 QAM
NA
-78.9
-78.4
32 QAM
NA
-75.1
-74.6
64 QAM
NA
-71.9
-71.4
128 QAM
NA
-70.7
-70.2
256 QAM
NA
-68.4
-67.9
256 QAM
NA
-65.8
-65.3
NA
-87.1
-86.6
8 PSK
NA
-82.5
-82.0
16 QAM
NA
-79.9
-79.4
32 QAM
NA
-76.1
-75.6
64 QAM
NA
-73.3
-72.8
128 QAM
NA
-70.8
-70.3
256 QAM
NA
-68.1
-67.6
256 QAM
NA
-65.3
-64.8
NA
-86.4
-85.9
8 PSK
NA
-81.1
-80.6
16 QAM
NA
-80.0
-79.5
32 QAM
NA
-75.8
-75.3
64 QAM
NA
-73.5
-73.0
128 QAM
NA
-70.5
-70.0
256 QAM
NA
-68.1
-67.6
256 QAM
NA
-65.1
-64.6
QPSK
QPSK
40MHz (FCC)
50MHz
56MHz
47MHz
52MHz
Page 44 of 52
8.6
Mechanical Specifications
RFU Dimensions
OCB Branching
(Split-Mount and Compact
All-Indoor )
IDU-RFU Connection
8.7

Height: 490 mm (19”)

Width: 144 mm (6”)

Depth: 280 mm (11”)

Weight: 7 kg (15 lbs) (excluding Branching)

Height: 420 mm (19”)

Width: 110 mm (6”)

Depth: 380 mm (11”)

Weight: 7 kg (15 lbs) (excluding Branching)

Recommended torque for RFU-OCB connection: 17 Nm
Coaxial cable RG-223 (up to 100 m/300 ft), Belden 9914/RG-8 (300
m/1000 ft) or equivalent, N-type connectors (male)
1500HP/RFU-HP Waveguide Flanges
The radio output port (C – Carrier) is frequency dependant, and is terminated
with the following waveguide flanges:
1500HP/RFU-HP – Waveguide Flanges
Frequency Band (GHz)
Waveguide Flanges
6L
CPR137
6H
CPR137
7
CPR112
8
CPR112
11
CPR90
Page 45 of 52
8.8
IDU Compatibility
IP-10G/E R1, R2, R3
1500HP 2RX
IP-10Q
1500R
3200T
IP-10G/E R1, R2, R3
1500HP 1RX
IP-10Q
1500R
3200T
IP-10G/E R2, R3
RFU-HP 1RX
IP-10Q
1500R
3200T
8.9
Environmental Specifications
Indoor Temperature Range -5°C to +45°C
Outdoor Temperature
Range
-35°C to +55°C
Relative Humidity
Up to 100% (all weather operation)
Operational
Storage Transportation
Safety
ETS 300 019-1-4 class 4.1, with an operating
temperature range of -50°C to 55°C.
 Storage: ETS 300 019-2-1 class T1.2, with a
temperature range of -25°C to+85°C.
 Transportation: ETS 300 019-2-2 class 2.3, with a
temperature range of -40°C to+85°C.
 UL 1950 and EN 60950
Page 46 of 52
8.10
RFU Models and Part Numbers
The following table lists and describes the available 1500HP/RFU-HP models.
RFU Models
Marketing Model
Description
15HP-RFU-7
1500HP 7G 2RX SM / All Indoor
15HP-RFU-8
15HP-RFU-6L
1500HP 6LG 2RX SM / All Indoor
15HP-RFU-6H
1500HP 6HG 2RX SM / All Indoor
15HP-RFU-11
15HPS-1R-RFU-7
1500HP 7G 1RX SM
15HPS-1R-RFU-8
1500HP 8G 1RX SM
15HPS-1R-RFU-6L
1500HP 6LG 1RX SM
15HPS-1R-RFU-6H
1500HP 6HG 1RX SM
15HPS-1R-RFU-11
1500HP 11G 1RX SM
15HPS-1R-RFU-11w
1500HP 11G 1RX SM 40M (24-40MHz channels)
15HPA-1R-RFU-7
1500HP 7G 1RX All Indoor
15HPA-1R-RFU-8
15HPA-1R-RFU-6L
1500HP 6LG 1RX All Indoor
15HPA-1R-RFU-6H
1500HP 6HG 1RX All Indoor
15HPA-1R-RFU-11
15HPA-2R-RFU-7
15HPA-2R-RFU-8
15HPA-2R-RFU-6L
1500HP 6LG 2RX All Indoor
15HPA-2R-RFU-6H
1500HP 6HG 2RX All Indoor
15HPA-2R-RFU-11
RFU-HP-1R-6H
RFU-HP 6HG 1Rx up to 56M SM / All Indoor
RFU-HP-1R-6L
RFU-HP 6LG 1Rx up to 56M SM / All Indoor
RFU-HP-1R-7
RFU-HP 7G 1Rx up to 56M SM / All Indoor
RFU-HP-1R-8
RFU-HP 8G 1Rx up to 56M SM / All Indoor
Page 47 of 52
8.11
OCB Part Numbers
The following table presents the various RFU options and the configurations
in which they are used.
OCB Part Numbers
Diversity/Non-Diversity
Split-Mount
Space Diversity IFC (2Rx) (6, 7, 8 ,11GHz)
15OCBf-SD-xxxY-ZZZ-H/L
Non Space Diversity (1Rx) (6, 7, 8GHz)
15OCBf-xxxY-ZZ-H/L
11GHz Non Space Diversity (1Rx)3
15OCB11w-xxxY-ZZ-H/L
OCB Part Numbers for All Indoor Compact
Diversity/Non-Diversity
All Indoor Compact
Space Diversity IFC (2Rx) (6, 7,8 GHz)
15OCBf-SD-xxxY-ZZ-H/L
Space Diversity IFC (2Rx) (11GHz)
15OCB11w-SD-xxxY-ZZ-H/L
Non Space Diversity (1Rx) (6, 7,8GHz)
15OCBf-xxxY-ZZ-H/L
11GHz Non Space Diversity (1Rx) 4
15OCB11w-xxxY-ZZ-H/L
8.11.1 OCB Part Number Format
Place Holder in
Marketing Model
Possible Values
f
6L,6H,7,8,11
xxx
000-999 [MHz]
TRS in MHz
Y
A…Z
Ceragon TRS block
designation
ZZZ
Examples:
Designation of the channels
the OCB is covering
1W3 – “Wide” filters covering channels 1-3
Description and
Remarks
03 – Only channel 03, 28MHz channel
3-5 – 56MHz “Narrow” filters allowing
concatenation using OCBs covering channels
3 and 4.
H/L
3
4
H or L
Designating TX High and TX
low
11GHz OCB is a wide BW OCB which supports up to 40MHz, while the other OCBs (6L, 6H, 7,
8GHz) support up to 30MHz.
11GHz OCB is a wide BW OCB which supports up to 40MHz, while the other OCBs (6L, 6H, 7,
8GHz) support up to 30MHz.
Page 48 of 52
8.12
Generic All-Indoor Configurations Part Numbers
The following tables contain a list of typical All-Indoor configurations.
All-Indoor Configurations (1+0 /1+1 HSB)
1+0 / 1+1 HSB
32T-f_1+0
3200T-f_1+0
32T-f_1+0_EW
3200T-f_1+0_East West
32T-f_1+0_SD
3200T-f_1+0_Space Diversity
32T-f_1+0_SD_EW
3200T-f_1+0_Space Diversity East West
32T-f_1+1_HSB
3200T-f_1+1_HSB
32T-f_1+1_HSB_EW
3200T-f_1+1_HSB_East West
32T-f_1+1_HSB_SD
3200T-f_1+1_HSB_Space Diversity
32T-f_1+1_HSB_SD_EW
3200T-f_1+1_HSB_Space Diversity East West
All-Indoor Configurations (N+0/N+1 XPIC)
N+0 / N+1 XPIC
32T-f_1+1/2+0_X
3200T-f_1+1/2+0 XPIC
32T-f_2+1/3+0_X
3200T-f_2+1/3+0 XPIC
32T-f_3+1/4+0_X
3200T-f_3+1/4+0 XPIC
32T-f_4+1/5+0_X
3200T-f_4+1/5+0 XPIC
32T-f_5+1/6+0_X
3200T-f_5+1/6+0 XPIC
32T-f_6+1/7+0_X
3200T-f_6+1/7+0 XPIC
32T-f_7+1/8+0_X
3200T-f_7+1/8+0 XPIC
32T-f_8+1/9+0_X
3200T-f_8+1/9+0 XPIC
32T-f_9+1/10+0_X
3200T-f_9+1/10+0 XPIC
Page 49 of 52
All-Indoor Configurations (N+0 / N+1 XPIC Space Diversity)
N+0 / N+1 XPIC Space Diversity
32T-f_1+1/2+0_X _SD
3200T-f_1+1/2+0 XPIC Space Diversity
32T-f_2+1/3+0_X _SD
32T-f_3+1/4+0_X_SD
32T-f_4+1/5+0_X_SD
32T-f_5+1/6+0_X_SD
32T-f_6+1/7+0_X_SD
32T-f_7+1/8+0_X_SD
32T-f_8+1/9+0_X_SD
All-Indoor Configurations (N+0 / N+1 XPIC Space Diversity)
N+0 / N+1 XPIC Space Diversity
32T-f_1+1/2+0_X _SD
32T-f_2+1/3+0_X _SD
32T-f_3+1/4+0_X_SD
32T-f_4+1/5+0_X_SD
32T-f_5+1/6+0_X_SD
32T-f_6+1/7+0_X_SD
32T-f_7+1/8+0_X_SD
32T-f_8+1/9+0_X_SD
32T-f_9+1/10+0_X_SD
32T-f_1+1/2+0_X_EW
3200T-f_1+1/2+0 XPIC East West
32T-f_2+1/3+0_X_EW
32T-f_3+1/4+0_X_EW
32T-f_4+1/5+0_X_EW
32T-f_1+1/2+0_X_SD_EW
3200T-f_1+1/2+0 XPIC East West Space Diversity
32T-f_2+1/3+0_X_SD_EW
32T-f_3+1/4+0_X_SD_EW
32T-f_4+1/5+0_X_SD_EW
Page 50 of 52
All-Indoor Configurations (N+0/N+1 Single Pol)
N+0/N+1 Single Pol
32T-f_1+1/2+0_SP
3200T-f_1+1/2+0_SP
32T-f_2+1/3+0_SP
3200T-f_2+1/3+0_SP
32T-f_3+1/4+0_SP
3200T-f_3+1/4+0_SP
32T-f_4+1/5+0_SP
3200T-f_4+1/5+0_SP
All-Indoor Configurations (N+0/N+1 Single Pol Space Diversity)
N+0/N+1 Single Pol Space Diversity
32T-f_1+1/2+0_SP_SD
3200T-f_1+1/2+0_Single Pole Space Diversity
32T-f_2+1/3+0_SP_SD
32T-f_3+1/4+0_SP_SD
32T-f_4+1/5+0_SP_SD
32T-f_1+1/2+0_SP_EW
3200T-f_1+1/2+0_Single Pole East West
32T-f_2+1/3+0_SP_EW
32T-f_3+1/4+0_SP_EW
32T-f_4+1/5+0_SP_EW
32T-f_1+1/2+0_SP_SD_EW
3200T-f_1+1/2+0_Single Pole Space Diversity East West
32T-f_2+1/3+0_SP_SD_EW
32T-f_3+1/4+0_SP_SD_EW
32T-f_4+1/5+0_SP_EW
All-Indoor Configurations (N+0/N+1 XPIC Upgrade ready)
N+0/N+1 XPIC Upgrade Ready
32T-f_1+1/2+0_X_UR
3200T-f_1+1/2+0_XPIC_Upgrade Ready
32T-f_2+1/3+0_X_UR
32T-f_3+1/4+0_X_UR
32T-f_4+1/5+0_X_UR
Page 51 of 52
All-Indoor Configurations (N+0/N+1 XPIC Space Diversity Upgrade-Ready)
N+0/N+1 XPIC Space Diversity Upgrade Ready
32T-f_1+1/2+0_X_SD_UR
3200T-f_1+1/2+0_XPIC_Space Diversity Upgrade Ready
32T-f_2+1/3+0_X_SD_UR
32T-f_3+1/4+0_X_SD_UR
32T-f_4+1/5+0_X_SD_UR
All-Indoor Configurations (19" Without Rack)
19" Without Rack
32T19-f_1+0_WO_rack
3200T19_inch-f_1+0_Without_rack
32T19-f_1+0_EW_WO_rack
3200T19_inch-f_1+0_East West Without rack
32T19-f_1+0_SD_WO_rack
3200T19_inch-f_1+0_Space Diversity Without rack
32T19-f_1+0_SD_EW_WO_rack
3200T19_inch-f_1+0_Space Diversity East West Without rack
32T19-f_1+1_HSB_WO_rack
3200T19_inch-f_1+1_HSB_Without_rack
32T19-f_1+1_HSB_SD_WO_rack
3200T19_inch-f_1+1_HSB_Space Diversity Without rack
32T19-f_1+1_HSB_EW_WO_rack
3200T19_inch-f_1+1_HSB_East West Without rack
32T19-f_1+1_HSB_SD_EW_WO_rack 3200T19_inch-f_1+1_HSB_Space Diversity East West Without rack
For additional configurations and details, please contact your Ceragon
representative.
Page 52 of 52

FibeAir® 1500HP/RFU-HP Technical Description

Transcription

Similar documents

How to make a saddle rack

Silego Technology - Globalpress Electronics Summit

Brochure AP-810-AH-T

RackBuilder® Delivered - Milestone AV Technologies

DVB-S/S2 to DVB-C transmodulator

VB262 DUAL QAM/8VSB INPUT MODULE

Tie Rack Operating Instructions

Invincible Rack - Husky Rack and Wire

Black-and-White Tabloids

Convergence Challenges for the SME