4RF N0400025A0200A POINT TO POINT DIGITAL RADIO SYSTEM (RECEIVER) User Manual USERS MANUAL 3

4RF Limited POINT TO POINT DIGITAL RADIO SYSTEM (RECEIVER) USERS MANUAL 3

USERS MANUAL 3

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Document ID	737488
Application ID	GXNBUgZ34dBv824iBSz38w==
Document Description	USERS MANUAL 3
Short Term Confidential	No
Permanent Confidential	No
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Document Type	User Manual
Display Format	Adobe Acrobat PDF - pdf
Filesize	268.89kB (3361122 bits)
Date Submitted	2006-12-12 00:00:00
Date Available	2006-12-14 00:00:00
Creation Date	2006-10-24 14:09:22
Producing Software	Acrobat Distiller 7.0.5 (Windows)
Document Lastmod	2006-11-30 12:46:43
Document Title	USERS MANUAL 3
Document Creator	Acrobat PDFMaker 7.0.7 for Word
Document Author:	Doug.Connor

Cross Connections | 134
QJET cross connections
Expand the E1 / T1 display by clicking on the relevant icons.
The QJET card can operate in several modes allowing you greater flexibility in tailoring or grooming
traffic. The Data type selection are Off, E1, or T1 rates.
Note: An unframed E1 / T1 port requires 5 bits (or 40 kbit/s) of overhead traffic per port for
synchronization.
An unframed E1 port with 2048 kbit/s of traffic requires 2088 kbit/s of link capacity.
An unframed T1 port with 1544 kbit/s of traffic requires 1584 kbit/s of link capacity.
Cross Connections | 135
For each port that you want to put into service, choose the required mode (either Unframed or
Framed):
Unframed mode
Leave the Framed checkbox unticked.
Select the required Data type from the drop-down list E1 or T1.
Local drop and insert connections are not possible between Unframed E1 / T1 ports.
Framed mode
Tick the Framed checkbox.
Select the required framed mode from the drop-down list:
Local drop and insert connections are possible between framed E1 ports on the same interface card or
E1 ports on different interface cards.
Local drop and insert connections are possible between framed T1 ports on the same interface card or
T1 ports on different interface cards.
Local drop and insert connections are not possible between framed E1 ports and framed T1 ports.
Cross Connections | 136
E1 Framed Modes
Framed Mode
Description
E1 – PCM 30
Provides 30 timeslots to transport traffic. Timeslot 16 carries channel
associated signalling data (CAS).
E1 – PCM 31
Provides 31 timeslots to transport traffic. Timeslot 16 can be used for common
channel signalling or to transport traffic.
E1 – PCM 30C
Same as E1 – PCM 30 mode but supports CRC-4.
E1 – PCM 31C
Same as E1 – PCM 31 mode but supports CRC-4.
E1 CRC-4 (cyclic redundancy check) is used to ensure correct frame alignment and also used to
gather E1 performance statistics e.g. Errored Seconds (ES), Severely Errored Seconds (SES).
The first three bits of timeslot 0 NFAS (bits 0,1 & 2) and all of timeslot 0 FAS are not transported
across the link, but rather terminated and regenerated at each terminal.
The last five bits of timeslot 0 NFAS (bits 3 – 7) are the National Use Bits (NUBs) which can be cross
connected locally or over the link.
E1 - PCM 30 mode
E1 - PCM 30 modes are used when access to the signalling bits (ABCD) is required, for example:

Splitting a PCM 30 E1 into two separate PCM 30 E1s

Cross connecting signalling from DFXS, DFXO or Q4EM interfaces into an PCM 30 E1

Drop and Insert connections between PCM 30 E1s
In PCM 30 / PCM 30C mode, the timeslot table left column is used to map timeslot bits and the
timeslot table right column is used to map CAS bits (ABCD) for signalling. Timeslot 16 is reserved to
transport the CAS multi frame.
One use of this mode is to connect the 4 wire E&M interfaces to third-party multiplexer equipment over
the E1 interface using CAS in TS16 to transport the E&M signalling.
To configure this mode correctly, you must have a detailed knowledge of the CAS signalling modes for
the third-party equipment to ensure the signalling bits are compatible and configured to interoperate.
E1 - PCM 31 mode
E1 - PCM 31 modes are used to cross connect timeslots bits without the signalling bits (ABCD).
TS16 can be cross connected between E1 ports (to transport the entire CAS multi frame) or used for
common channel signalling or to transport traffic.
The timeslot table left column is used to map timeslot bits but the timeslot table right column for CAS
bits (ABCD) is not used.
Cross Connections | 137
T1 Framed Modes
Framed Mode
Description
T1 - SF
Provides 24 timeslots to transport traffic using the G.704 12 frame Super
Frame without signalling. There is no CRC capability with the SF.
T1 – SF 4
Provides 24 timeslots to transport traffic using the G.704 12 frame Super
Frame with 4 state signalling (AB bits). There is no CRC capability with the SF.
T1 – ESF
Provides 24 timeslots to transport traffic using the G.704 24 frame Extended
Super Frame with CRC and without signalling.
T1 – ESF 4
Provides 24 timeslots to transport traffic using the G.704 24 frame Extended
Super Frame with CRC and 4 state signalling (AB bits).
T1 – ESF 16
Provides 24 timeslots to transport traffic using the G.704 24 frame Extended
Super Frame with CRC and 16 state signalling (ABCD bits).
For the 24 framed modes of ESF 4 and ESF 16, the Data Link bit is shown in the timeslot table but is
currently unavailable for use.
T1 - SF mode
T1 SF mode provides 24 timeslots to transport traffic using the G.704 12 frame Super Frame without
demultiplexing the signalling. Complete timeslots can be cross connected including the inherent
robbed signalling bits.
The timeslot table left column is used to map timeslot bits but the timeslot table right column for CAS
bits (ABCD) is not used.
T1 SF mode is used when access to the signalling bits is not required but are transported between
T1s, for example:

Drop and Insert connections between 12 frame Super Frame T1s or data interfaces
T1 - SF 4 mode
T1 SF 4 mode provides 24 timeslots to transport traffic using the G.704 12 frame Super Frame with
four state demultiplexed signalling using the AB bits.
The mapping left column is used to map timeslot bits and the timeslot table right column is used to
map the CAS A&B bits for signalling (C&D bits are not used).
T1 SF mode is used when access to the signalling bits is required, for example:

Cross connecting signalling from DFXS, DFXO or Q4EM interfaces into a 12 frame Super
Framed T1 using ‘multiplexed’ signalling from the interface.

Drop and Insert connections between 12 frame Super Framed T1s or data interfaces
T1 - ESF mode
T1 ESF mode provides 24 timeslots to transport traffic using the G.704 12 frame Extended Super
Frame without demultiplexing the signalling. Complete timeslots can be cross connected including the
inherent robbed signalling bits.
The timeslot table left column is used to map timeslot bits but the timeslot table right column for CAS
bits (ABCD) is not used.
T1 ESF mode is used when access to the signalling bits is not required but are transported between
T1s, for example:

Drop and Insert connections between 24 frame Extended Super Framed T1s or data interfaces
Cross Connections | 138
T1 - ESF 4 mode
T1 ESF 4 mode provides 24 timeslots to transport traffic using the G.704 24 frame Extended Super
Frame with four state demultiplexed signalling using the AB bits each with a bit rate of 667 bit/s.
The mapping left column is used to map timeslot bits and the timeslot table right column is used to
map the CAS A&B bits for signalling (C&D bits are not used).
T1 ESF 4 mode is used when access to the signalling bits is required, for example:

Cross connecting signalling from DFXS, DFXO or Q4EM interfaces into a 24 frame Extended
Super Framed T1 using ‘multiplexed’ signalling from the interface.

Drop and Insert connections between 24 frame Extended Super Framed T1s or data interfaces
T1 - ESF 16 mode
T1 ESF 16 mode provides 24 timeslots to transport traffic using the G.704 24 frame Extended Super
Frame with sixteen state demultiplexed signalling using the ABCD bits each with a bit rate of 333 bit/s.
The mapping left column is used to map timeslot bits and the timeslot table right column is used to
map the CAS ABCD bits for signalling.
T1 ESF 16 mode is used when access to the signalling bits is required, for example:

Cross connecting signalling from DFXS, DFXO or Q4EM interfaces into a 24 frame Extended
Super Framed T1 using ‘non-multiplexed’ signalling from the interface.

Drop and Insert connections between 24 frame Extended Super Framed T1s or data interfaces
Cross Connections | 139
Selecting and mapping bits and timeslots
This section describes how to select and map:

a single bit

multiple bits

a 64 kbit/s timeslot

multiple timeslots
Selecting a single bit
Each timeslot is represented by 8 rectangles (each representing a single bit). Each bit can carry 8
kbit/s.
One or more consecutive bits can be selected in a timeslot if a rate of greater than 8 kbit/s is required.
1. Click on the rectangle that represents the bit you require. It will turn red.
2. Click and drag this bit to the rectangle representing the bit on the interface you want it to be
connected to, and release the mouse button.
The red rectangle will be replaced by the allocated connection number at each interface.
Cross Connections | 140
Selecting multiple bits
It is possible to select multiple consecutive bits if circuit capacity of greater than 8 kbit/s is required.
1. Click the first bit, and then hold down the Ctrl key while selecting the remaining bits.
2. Click and drag the whole block by clicking the bit on the left hand side of your selection, and drag
to the required interface. Release the mouse button.
Tip: It is also possible to select multiple bits by holding down the Shift key, and dragging across
the required rectangles.
Differing numbers of bits display in different colors when the cross-connect is completed:
Cross Connections | 141
Selecting a 64 kbit/s timeslot
1. Click on the TSX timeslot number (where X is the desired timeslot from 1 to 31).
Alternatively, right-click over any of the bits in the timeslot, and click on Select Timeslot.
2. Drag and drop in the normal way to complete the cross connection.
Selecting multiple non consecutive timeslots
1. Click on one TSn timeslot number (where n is the desired timeslot 1 to 31).
2. Hold down the Ctrl key while clicking on each of the required timeslot numbers.
3. Drag and drop in the normal way to complete the cross connection.
Cross Connections | 142
Selecting multiple consecutive timeslots
1. Click on the first TSn timeslot number (where n is the desired timeslot 1 to 31).
2. Hold down the Shift key while clicking on the last required timeslot number.
3. Drag and drop in the normal way to complete the cross connection.
Selecting all timeslots in a port
1. Right-click over any of the rectangles.
2. Click Select All.
Cross Connections | 143
Q4EM cross connections
1. Expand the Q4EM display by clicking the relevant
icon.
2. Set the Voice capacity by selecting 16, 24, 32, or 64 kbit/s rates.
3. Drag and drop from the Voice mapping connection box to the required partner interface to create
the voice cross connection.
4. If E&M signalling is required, drag and drop from the Signalling mapping connection box to the
required partner interface to create the E&M cross connection.
Cross Connections | 144
DFXS & DFXO cross connections
1. On one side of the link, expand the DFXS display, as required, by clicking
2. On the other side of the link, expand the corresponding DFXO display, as required, by clicking
3. For the DFXS card and corresponding DFXO card, select the Signalling type as required,
according to the table below. The CAS signalling between DFXO / DFXS interfaces uses 4RF
proprietary allocation of control bits.
The Signalling type affects both ports of the DFXO / DFXS interface. If a mixture of signalling
types is required, then multiple DFXO / DFXS cards are needed.
Signalling
Application
Overhead
Multiplexed
(default)
Multiplexers the four ABCD bits from the interface into a
single 8 kbit/s channel.
Use when interworking DFXO to DFXS, between an XE
and a SE radio or when limited bandwidth is available.
This signalling type cannot be used for interworking
between framed E1 and voice interfaces.
8 kbit/s
Non-multiplexed
Transports each of the four ABCD bits in separate 8 kbit/s
channels.
Use when interworking DFXO cards to DFXS cards or
when signalling bits are mapped into an E1 / T1 timeslot.
32 kbit/s
4 wire compatible
Use when interworking the DFXO card or DFXS card to a
Q4EM interface
8 kbit/s
•
DFXS to DFXO A bit mapped to off-hook
•
DFXO to DFXS A bit mapped to fault
4. Set the Voice capacity and create the Voice connection by dragging and dropping between the
mapping connection boxes of the DFXO and DFXS corresponding ports.
5. Link the Port Signalling connection by dragging and dropping between the mapping connection
boxes of the DFXO and DFXS corresponding ports. The DFXO / DFXS control signals (off hook,
ring, etc) will not function without this connection.
Cross Connections | 145
QV24 cross connections
1. Expand the QV24 displays, as required, by clicking the relevant
icons.
2. Select the Port Baud Rate as required (default is 9600).
3. Drag and drop to the required partner interface to create the V.24 Data connection.
If the partner interface is a QJET:

If the V.24 Baud Rate selected is 38400 is less, drag from the QV24 mapping connection box
to the QJET timeslot. The correct QJET capacity for the baud rate selected will automatically
be assigned.

If the V.24 Baud Rate selected is greater than 38400, select the QJET capacity required, as
per the following table, and drag from the QJET to the QV24 mapping connection box.
Baud Rate
Bits Required
Bit Rate
300 - 7200
16 kbit/s
9600 - 14400
24 kbit/s
19200 - 23040
32 kbit/s
28800
40 kbit/s
38400
48 kbit/s
57600
72 kbit/s
115200
16
128 kbit/s
Cross Connections | 146
HSS cross connections
1. Expand the HSS displays, as required, by clicking the relevant
icons.
2. Select the Synchronous Clock Selection mode (see “HSS synchronous clock selection modes”
on page 114).
3. Set the Data rate to a value between 8 and 2048 (in multiples of 8 kbit/s).
The net data rate available to the user is defined by Data Rate – overhead
e.g. a date rate set to 2048 kbit/s with an overhead of 40 kbit/s provides a user data rate of 2008
kbit/s
4. Drag and drop to the required partner interface to create the HSS Data connection.
If the partner interface is a QJET, select the capacity on the QJET and drag it to the HSS Data
mapping connection box.
The QJET capacity selected must be the sum of the data rate required plus the overhead rate
selected.
5. Drag and drop to the required partner interface to create the HSS Signalling cross connection. A
minimum of 8 kbit/s of capacity is required and must be set symmetrically at both ends of the link.
Cross Connections | 147
Cross connection example
This is an example of cross connection mapping:
Circuit
Local port
Remote port
Radio management
User Ethernet
Capacity
(kbit/s)
Connection
numbers
64
1024
3 wire E&M circuit
Q4EM port 1
(slot C)
Q4EM port 1
(slot C)
72
7/15
Unframed E1 data
QJET port 1
(slot D)
QJET port 1
(slot D)
2088
65
Unframed T1 data
QJET port 2
(slot D)
QJET port 2
(slot D)
1584
66
Loop Interface
DFXO port 1
(slot E)
DFXS port 1
(slot E)
72
8/32
V.24 data circuit
9600
QV24 port 1
(slot G)
QV24 port 1
(slot G)
24
14
HSS data circuit
1024 kbit/s
HSS port 1
(slot H)
HSS port 1
(slot H)
1088
31/16
Cross Connections | 148
Symmetrical Connection Wizard
The Cross Connections application has a Symmetrical Connection Wizard which simplifies the cross
connection configuration when the terminals are fitted with symmetrical / matching interface types.
A symmetrical connection is a connection between the local and the remote terminal where the local
slot, card type, port and connection details are identical to those of the remote terminal.
The only exception is DFXO / DFXS connections where DFXO cards are considered to match DFXS
cards (as they normally interwork).
Framed E1 / T1 CAS connections, drop-and-insert connections, and connections that do not involve
entire timeslots, are considered to be asymmetrical.
Starting the wizard
When starting the wizard with unsaved changes, the following popup dialog should appear
Click on 'Save' if you wish to save the current configuration to a file. Clicking on 'Continue' will continue
with the wizard and overwrite any changes made when the wizard finishes.
The wizard can be cancelled at any time by clicking on the 'Cancel' button or by closing the window.
Wizard Navigation
Click on the Next button to progress through the wizard. The current stage is indicated in the
navigation bar on the left. You can jump directly to a stage by clicking on the stage required.
Cross Connections | 149
Setting the IP address
If the local or remote terminal IP addresses have been setup, they will be displayed in the Local and
Remote fields. If the IP addresses are not displayed, enter the IP addresses of the local and remote
terminals.
Click on 'Get Configuration' to upload the existing cross connections configuration from the local
terminal. The Radio bandwidth bar will show the available bandwidth and will be updated as bandwidth
is assigned to cards.
Setting the bandwidth
If the Cross Connections Application is opened from SuperVisor, the Total Capacity of the radio link
will be shown in the Bandwidth field.
If the Cross Connections Application is opened as a stand alone application, the Total Capacity of the
radio link will be need to be entered in the Bandwidth field.
The 'Remove asymmetrical connections' button will be active if there are existing asymmetrical cross
connections. If you want to remove existing asymmetrical cross connections, click on this button. The
Radio bandwidth bar will update accordingly.
Cross Connections | 150
Card Selection
If the Cross Connections Application is opened from SuperVisor, existing cards installed in the local
terminal that match cards installed in the remote terminal will be displayed. Mismatched cards will be
shown as 'Empty Slot'.
If the Cross Connections Application is opened as a stand alone application, select the card types that
will be fitted in the terminal.
To copy the card type selected in Slot A to all the other slots (B – H), click on the Copy
Card button. This assumes that the same interface card types are fitted in all the card
slots.
Cross Connections | 151
Interface configurations
Setup the interface configurations as per the wizard instructions. Existing asymmetrical connections
will be replaced with symmetrical connections if an interface parameter is changed.
Q4EM
QJET
DFXO / DFXS
QV24
HSS
Ethernet
To copy the port configuration selected in Port 1 to all the other ports on the card, click on
the Copy Port button.
To copy the card configuration to all other cards of the same type fitted in the terminal,
click on the Copy Card button. This can save time when setting up multiple cards of the
same type.
Cross Connections | 152
Symmetrical connection summary
Click Finish.
Send symmetrical connection configuration
Click OK to send the configuration to the terminals.
The process is completed.
Note: The wizard may change the connection numbers of existing connections.
Protected terminals | 153
11. Protected terminals
Monitored Hot Stand By (MHSB)
This section describes configuring the protected terminal in MHSB mode. A protected terminal in
MHSB mode comprises two radios interconnected using the tributary and RF switches as shown
below:
The MHSB switch protects terminals against any single failure in one radio. It also monitors the alarm
output of each radio and switches between radios if major radio link alarms occur.
The MHSB switch uses a CPU to monitor the alarm status received from both the connected radios'
alarm ports. When a relevant major radio link alarm is detected on the active radio (that is, transmitter,
receiver, power supply or modem), the CPU switches a bank of relays that switches all the interfaces
and the transmit port from the main radio to a functioning stand-by radio. The stand-by radio now
becomes the active radio.
The tributary switch and the RF switch are both a 19-inch rack-mount 1U high chassis. The total rack
space required is 6U. The MHSB switch option is available for the following bands: 300, 400, 700, 900,
1400, 2000, and 2500 MHz.
Protected terminals | 154
Tributary switch front panel
No.
Description
Explanation
Power supply input
Input for DC power or AC power
Protective earth
M5 terminal intended for connection to an external protective
conductor for protection against electric shock in case of a fault
Interface ports
Port for connecting to customer interface equipment
Radio A interfaces
These connect to the interface ports on radio A
Radio B interfaces
These connect to the interface ports on radio B
Console
For factory use only
Ethernet
Port for connecting to customer Ethernet network. This port is also
used to set up and manage the radios remotely over an IP
network
Radio A Ethernet
Connects to an Ethernet port on radio A
Radio B Ethernet
Connects to an Ethernet port on radio B
10
Alarms
Alarm input/output connections for customer equipment
11
Radio A alarms
Connects to the alarm port on radio A
12
Radio B alarms
Connects to the alarm port on radio B
13
RF SW
Provides power and signalling to the RF switch
14
Mode switch
Three-position locking toggle switch to set the MHSB switch into
automatic mode or radio A / radio B test mode
15
LEDs
Mode and status LEDs
Protected terminals | 155
Tributary protection switch LEDs
LED
Colour
Appearance
Explanation
Green
Solid
The radio is active and is OK
Green
Flashing
The radio is in standby mode and is OK
Red
Solid
The radio is active and there is a fault
No colour (off)
The tributary switch is in 'slave' mode and the
switching is controlled by the master tributary
switch
Red
Flashing
The radio is in standby mode, and there is a fault
Green
Solid
The radio is active and is OK
Green
Flashing
The radio is in standby mode and is OK
Red
Solid
The radio is active and there is a fault
No colour (off)
The tributary switch is in 'slave' mode and the
switching is controlled by the master tributary
switch
Red
Flashing
The radio is in standby mode, and there is a fault
Green
Solid
The tributary protection switch is in 'auto' mode
Green
Flashing
The tributary protection switch is in 'slave' mode
Red
Solid
The tributary protection switch is in 'manual' mode
(A or B)
Blue
Solid
Indicates that there is power to the tributary
protection switch
On
RF switch front panel
No.
Description
Explanation
Radio QMA
QMA connectors for connecting the protected radios
Protective earth
M5 terminal intended for connection to an external protective
conductor for protection against electric shock in case of a fault
Antenna port
N-type female connector for connection to the antenna feeder
cable. This view shows an internally mounted duplexer. If an
external duplexer is fitted, the antenna port will be on the external
duplexer
Slave tributary switch
outputs
Connects to secondary tributary switch for control of additional
interfaces
Tributary switch
Connects the RF switch to the tributary switch (the master if more
than one tributary switch is required)
LEDs
Status LEDs
Protected terminals | 156
RF protection switch LEDs
LED
Colour
Appearance
Explanation
Tx A
Green
Solid
RF is being received from radio A
Tx B
Green
Solid
RF is being received from radio B
On
Blue
Solid
Indicates that there is power to the RF protection switch
Slave tributary switches
Each tributary switch protects up to eight ports. Up to three slave tributary switches may be added to a
MHSB terminal to protect up to 32 ports. Each slave tributary switch is interconnected by means of the
slave tributary switch ports on the RF switch, as shown below.
Note: A tributary switch that is operating as a slave (rather than a master) has a RJ-45 V.24 loopback
connector plugged into the console port. If the connector is missing, contact Customer Support.
Alternatively, you can make this connector. Follow the standard pinouts for a V.24 RJ-45 connection
(see "QV24 Interface connections" on page 228).
Protected terminals | 157
MHSB cabling
The two radios are interconnected as follows:
Caution: Do not connect Transmit to Receive or Receive to Transmit as this may damage the radio or
the MHSB switch.
Cables supplied with MHSB
The following cables are supplied with a MHSB terminal:

Ethernet interface: RJ-45 ports standard TIA-568A patch cables .

Alarm interface: RJ-45 ports standard TIA-568A patch cables.

RF ports: two QMA male patch cables are supplied.
MHSB power supply
See “DC power supply” on page 32 and “AC power supply” on page 35.
Protected terminals | 158
Configuring the radios for protected mode
The MHSB switch does not require any special software. However, the radios connected to the MHSB
switch must be configured to work with the MHSB switch. This sets the alarm outputs and inputs to
function in MHSB mode.
You must configure the interfaces of both radios connected to the MHSB switch identically. To perform
this, you can either connect directly to the radio or use the test mode of the MHSB switch.
IP address setup
Before configuring the link, you must ensure that the two independent links have correctly configured
IP address details.
All four radios in the protected link must be on the same subnet.
Protected terminals | 159
Mounting the MHSB radios and switch
Once the IP addresses are correctly configured, it is important to connect the A and B radios' Ethernet
and Alarm ports correctly. In general, mount radio A above the MHSB switch and radio B below the
MHSB switch:
There is an Ethernet connection between any of the four Ethernet ports on each radio and the
Ethernet port on the Tributary switch. There is also a connection between radio A and radio B, which
ensures Ethernet traffic is maintained if a radio loses power.
The Ethernet port on the protection switch can be connected to an Ethernet hub or switch to allow
multiple connections.
Important: The management Ethernet capacity on each of the four radios in the protected terminal
must be identical for remote communications to work and there should only be one IP connection to
the management network (via the tributary switch Ethernet port).
Protected terminals | 160
Configuring the terminals for MHSB
It is recommended that you configure the local and remote A side first, then the local and remote B
side. Both the local A and B radios must be configured identically, and both the remote A and B radios
must be configured identically.
Tip: As illustrated below, you may find it helpful to have two browser sessions running simultaneously.
You can then easily see both the A and B sides of the protected link.
To configure MHSB operation:
1. Select Link > Maintenance > MHSB.
2. Enable MHSB mode.
3. Select whether the radio is A or B.
Ensure that the radio connected to the A side of the protection switch (normally above the MHSB
switch) is set to Radio A and the radio connected to the B side of the protection switch (normally
below the MHSB switch) is set to Radio B.
In the event of a power outage, the radios will switch over to the A side of the protection switch
when the power is restored. The A side is also the default active side.
4. When you have made your changes, click Apply to apply changes or Reset to restore the previous
configuration.
5. Repeat steps 2 to 4 for the other side of the protected link.
Protected terminals | 161
Clearing MHSB alarms
If a switchover event occurs, the OK LED on the front panel and on the Terminal status and menu bar
in SuperVisor changes to orange.
1. Select Clear Switched Alarm from the MHSB Command drop-down list.
2. Click Apply to apply changes or Reset to reset the page.
Note: When MHSB mode is enabled, external alarm input 2 is used by the protection system to carry
alarms from the protection switch to the radio. In MHSB mode, therefore, only external alarm input 1 is
available for user alarms.
In-service commissioning | 163
12. In-service commissioning
Before you start
When you have finished installing the hardware, RF and the traffic interface cabling, the system is
ready to be commissioned. Commissioning the terminal is a simple process and consists of:
1. Powering up the terminals
2. Configuring both the local and remote terminals using SuperVisor
3. Aligning the antennas
4. Synchronizing the terminals
5. Testing the link is operating correctly. As a minimum, conduct the suggested tests to ensure
correct operation. More extensive testing may be required to satisfy the end client or regulatory
body requirements.
6. Connecting up the client or user interfaces
What you will need

Appropriately qualified commissioning staff at both ends of the link.

Safety equipment appropriate for the antenna location at both ends of the link.

Communication equipment, that is, mobile phones or two-way radios.

SuperVisor software running on an appropriate laptop, computer, or workstation at one end of the
link.

Tools to facilitate loosening and re-tightening the antenna pan and tilt adjusters.

Predicted receiver input levels and fade margin figures from the radio link budget (You can use
Surveyor (see "Path planning" on page 19) to calculate the RSSI, fade margin, and availability).
In-service commissioning | 164
Applying power to the terminals
Caution:
Before applying power to a terminal, ensure you have connected the safety earth and antenna cable.
Apply power to the terminals at each end of the link.
When power is first applied, all the front panel LEDs will illuminate red for several seconds as the
system initializes.
After the system is initialized, the OK LED on the front panel should illuminate green and if the
terminals are correctly configured, the TX and RX LED should also be illuminated green.
If the RX LED is:

Red — the antennas are may be significantly mis-aligned with no signal being received.

Orange — the antennas may be roughly aligned with some signal being received.

Green — the antennas are well-aligned and adequate signal is being received to create a
reliable path.
If the TX LED is:

Red — there is a fault in the antenna or feeder cable, or the transmitter is faulty.

Green — this means the transmitter is working normally.
Review the link configurations using SuperVisor
1. Connect a PC, with SuperVisor installed, to both terminals in the link.
2. Log into the link.
3. Select Link > Summary and confirm the following basic information:
Terminal IP address(es)

Terminal TX and RX frequencies

RSSI (dBm)

TX power (dBm)

SNR (dBm)
Note: If the terminals have not already been configured, refer to "Configuring the terminal" on page
61, "Configuring the traffic interfaces" on page 77, and "Configuring the traffic cross connections" on
page 121.
In-service commissioning | 165
Antenna alignment
For any point-to-point link, it is important to correctly align the antennas to maximize the signal
strength at both ends of the link. Each antenna must be pointing directly at the corresponding antenna
at the remote site, and they must both be on the same polarization. The antennas are aligned visually,
and then small adjustments are made while the link is operating to maximize the received signal.
Directional antennas have a radiation pattern that is most sensitive in front of the antenna, in line with
the main lobe of the radiation pattern. There are several other lobes (side lobes) that are not as
sensitive as the main lobe in front of the antenna.
For the link to operate reliably, it is important that the main lobes of both antennas are aligned. If any
of the side lobes are aligned to the opposite antenna, the received signal strength of both terminals will
be lower, which could result in fading. If in doubt, check the radiation patterns of the antennas you are
using.
Checking the antenna polarization
Check that the polarization of the antennas at each end of the link is the same.
Antenna polarization of grid antennas are normally indicated by an arrow or with “H” and “V” markers
(indicating horizontal and vertical).
On Yagi antennas, ensure the orientation of the elements are the same at each end of the link.
Transmit frequency and power, and antenna polarization would normally be defined by a regulatory
body, and typically licensed to a particular user. Refer to your license details when setting the antenna
polarization.
In-service commissioning | 166
Visually aligning antennas
1. Stand behind the antenna, and move it from side to side until it is pointing directly at the antenna
at the remote site. The remote antenna may be made more visible by using a mirror, strobe light,
or flag.
If the remote end of the link is not visible (due to smoke, haze, or local clutter, etc), align the
antenna by using a magnetic compass. Calculate the bearing using a scale map of the link path.
When setting the antenna on the desired bearing ensure that you use the appropriate true-north to
magnetic-north offset. Also ensure that the compass reading is not affected by standing too close
to metallic objects.
2. Once the antenna is pointing at the remote antenna, tighten the nuts on the U-bolt or antenna
clamp just enough to hold it in position. Leave the nuts loose enough so that small adjustments
can still be made. Check that the antenna is still pointing in the correct direction.
3. Move the antenna up or down until it is pointing directly at the remote site.
4. Tighten the elevation and azimuth adjustment clamps.
5. Mark the position of the antenna clamps so that the antenna can be returned to this rough aim
point easily when accurately aligning the antennas.
6. Repeat steps 1-5 at the opposite site.
Note: Low gain antennas need less adjustment in elevation as they are simply aimed at the horizon.
They should always be panned horizontally to find the peak signal.
In-service commissioning | 167
Accurately aligning the antennas
Once the antennas are visually aligned, accurately align both antennas by carefully making small
adjustments while monitoring the RSSI. This will give the best possible link performance.
Note: Remember that it is important to align the main radiation lobes of the two antennas to each
other, not any side lobes. It may be easier to perform this procedure if you can communicate with
someone at the remote site by telephone, mobile, or two-way radio.
1. Connect a laptop PC running SuperVisor software and power up the terminals at both ends of the
link. Select Link > Performance > Summary so that you can see the RSSI indication for the local
terminal. Alternatively, use the RSSI test point on the front panel together with a multimeter (see
"Measuring the RSSI” on page 168).
2. Move the antenna through a complete sweep horizontally (known as a 'pan') either side of the
point established in the visual alignment process above. Note down the RSSI reading for all the
peaks in RSSI that you discover in the pan.
3. Move the antenna to the position corresponding to the maximum RSSI value obtained during the
pan. Move the antenna horizontally slightly to each side of this maximum to find the two points
where the RSSI drops slightly.
4. Move the antenna halfway between these two points and tighten the clamp.
5. If the antenna has an elevation adjustment, move the antenna through a complete sweep (known
as a 'tilt') vertically either side of the point established in the visual alignment process above. Note
down the RSSI reading for all the peaks in RSSI that you discover in the tilt.
6. Move the antenna to the position corresponding to the maximum RSSI value obtained during the
tilt. Move the antenna slightly up and then down from the maximum to find the two points where
the RSSI drops slightly.
7. Move the antenna halfway between these two points and tighten the clamp.
8. Recheck the pan (steps 2-4) and tighten all the clamps firmly.
9. Perform steps 1-8 at the remote site.
In-service commissioning | 168
Measuring the RSSI
Measure the RSSI value with a multimeter connected to the RSSI test port on the front of the terminal
(see "Front panel connections and indicators" on page 27).
1. Insert the positive probe of the multimeter into the RSSI test port, and clip the negative probe to
the chassis of the terminal (earth).
2. Pan and tilt the antenna until you get the highest VDC reading. The values shown in the table
below relate the measured VDC to the actual received signal level in dBm regardless of bandwidth
and frequency.
RSSI test
port value
(VDC)
RSSI
reading
(dBm)
RSSI test
port value
(VDC)
RSSI
reading
(dBm)
RSSI test
port value
(VDC)
RSSI
reading
(dBm)
0.000
- 100
0.675
- 73
1.350
- 46
0.025
- 99
0.700
- 72
1.375
- 45
0.050
- 98
0.725
- 71
1.400
- 44
0.075
- 97
0.750
- 70
1.425
- 43
0.100
- 96
0.775
- 69
1.450
- 42
0.125
- 95
0.800
- 68
1.475
- 41
0.150
- 94
0.825
- 67
1.500
- 40
0.175
- 93
0.850
- 66
1.525
- 39
0.200
- 92
0.875
- 65
1.550
- 38
0.225
- 91
0.900
- 64
1.575
- 37
0.250
- 90
0.925
- 63
1.600
- 36
0.275
- 89
0.950
- 62
1.625
- 35
0.300
- 88
0.975
- 61
1.650
- 34
0.325
- 87
1.000
- 60
1.675
- 33
0.350
- 86
1.025
- 59
1.700
- 32
0.375
- 85
1.050
- 58
1.725
- 31
0.400
- 84
1.075
- 57
1.750
- 30
0.425
- 83
1.100
- 56
1.775
- 29
0.450
- 82
1.125
- 55
1.800
- 28
0.475
- 81
1.150
- 54
1.825
- 27
0.500
- 80
1.175
- 53
1.850
- 26
0.525
- 79
1.200
- 52
1.875
- 25
0.550
- 78
1.225
- 51
1.900
- 24
0.575
- 77
1.250
- 50
1.925
- 23
0.600
- 76
1.275
- 49
1.950
- 22
0.625
- 75
1.300
- 48
1.975
- 21
0.650
- 74
1.325
- 47
2.000
- 20
In-service commissioning | 169
Synchronizing the terminals
After you have completed the alignment of the two antennas, you must ensure the two terminals are
synchronized.
The terminals are synchronized when:

the OK LED is green, which indicates that no system alarms are present, and

the RX LED is green, which indicates a good signal with no errors, and

the TX LED is green, which indicates that there are no transmitter fault conditions.
Checking performance
The amount of testing performed on the completed installation will depend on circumstances. Some
customers may need to prove to a local licensing regulatory body that the link complies with the
license provisions. This may require special telecommunications test equipment to complete these
tests. Most customers simply want to confirm that their data traffic is successfully passing over the link,
or that the customer interfaces comply with known quality standard.
However, the most important performance verification checks are:

Receive input level

Fade margin

Long-term BER
Checking the receive input level
The received signal strength at the local terminal is affected by many components in the system and
has a direct relationship with the resulting performance of the link. A link operating with a lower than
expected signal strength is more likely to suffer from degraded performance during fading conditions.
The receive input level of a link is normally symmetrical (that is, similar at both ends).
1. Compare the final RSSI figure obtained after antenna alignment with that calculated for the link.
2. If the RSSI figure is in excess of 3 dB down on the predicted level, recheck and correct problems
using the table below and then recheck the RSSI. Alternatively, recheck the link budget
calculations.
Possible cause
Terminal(s)
Is the terminal operating on the correct frequency?
Local & remote
Is the remote terminal transmit power correct?
Remote
Are all the coaxial connectors tight?
Local & remote
Is the antenna the correct type, that is, gain and frequency of operation?
Local & remote
Is the antenna polarized?
Local & remote
Is the antenna aligned?
Local & remote
Is the path between the terminals obstructed?
Note: If following the above steps does not resolve the situation, contact Customer Support for
assistance.
3. Record the RSSI figure on the commissioning form.
4. Repeat steps 1 to 2 for the other end of the link.
In-service commissioning | 170
Checking the fade margin
The fade margin is affected by many components in the system and is closely related to the received
signal strength. A link operating with a lower than expected fade margin is more likely to suffer from
degraded performance during fading conditions. A reduced fade margin can be due to operating the
link too close to the noise floor, or the presence of external interference. The fade margin of a link can
be asymmetrical (that is, different at each end).
Possible causes of low fade margin are as follows:
Problem
Terminal
Low receive signal strength (see above table)
Local and Remote
Interfering signals on the same, or very close to, the frequency of the
local terminal receiver.
Local
Intermodulation products that land on the same or very close to the
frequency of the local terminal receiver.
Local or Remote
Operating near the local receiver noise floor
Local
To check the fade margin:
1. Confirm (and correct if necessary) the receive input level (see the previous test).
Note: If the receive input level is lower than expected, the fade margin may also be low.
2. Select Link > Performance > Summary and check the current BER of the link in its normal
condition is better than 10-6 (If necessary, clear out any extraneous errors by clicking Reset
Counters).
3. Check the signal to noise (S/N) indication on the Link > Performance > Summary page. This
shows the quality of the signal as it is being processed in the modem. It should typically be better
than 30 dB. If it is less than 25 dB, it means that either the RSSI is very low or in-band interference
is degrading the S/N performance.
4. Temporarily reduce the remote site's transmit power using either an external attenuator or
SuperVisor (Remote > Terminal > Basic).
Note: Ideally, the transmit power of the remote site should be reduced by up to 20 dB, which will
require the use of an external 50 ohm coaxial attenuator capable of handling the transmit power
involved. In the absence of an attenuator, reduce the transmit power using SuperVisor.
5. Check and note the current BER of the link in its now faded condition (Again, if necessary, clear
out any extraneous errors (introduced by the power reduction step above) by clicking Reset
Counters).
6. Compare the unfaded and faded BER performance of the link (steps 2 and 4). Continue to reduce
the remote transmit power until either the BER drops to 10-6 or the remote transmitter power has
been reduced by 20 dB.
Note: The fade margin of the link is expressed as a number (of dB) that the link can be faded
(transmitter power reduced) without reducing the BER below operating specifications (1 * 10-6
BER). A 20 dB fade margin is adequate for most links.
In-service commissioning | 171
7. Record the fade margin and SNR results on the commissioning form.
Note: If the transmit power is reduced using SuperVisor rather than an external attenuator, the
fade margin should be recorded as “Greater than x dB” (where x = the power reduction).
8. Restore the remote terminal transmit power to normal.
9. Repeat steps 1 to 7 for the other end of the link.
Note: If following all the guidelines above does not resolve the situation, contact Customer
Support for assistance.
Checking long-term BER
The BER test is a measure of the stability of the complete link. The BER results of a link can be
asymmetrical (that is, different at each end).
1. Select Link > Performance > Summary and check the current BER and error counters of the link.
(If necessary, clear out any extraneous errors by selecting Reset Counters).
2. Wait 15 minutes, and check the BER display and error counters again. If there are a small number
of errors and the BER is still better than 10-9, continue the test for 24 hours. If there are a
significant number of errors, rectify the cause before completing the 24 hour test.
Note: It is normal to conduct the BER test in both directions at the same time, and it is important
that no further work be carried out on the equipment (including the antenna) during this period.
3. The BER after the 24 hour test should typically be better than 10-8.
4. Record the BER results on the commissioning form.
Bit Error Rate tests
A Bit Error Rate (BER) test can be conducted on the bench, (see “Bench setup” on page 37).
Attach the BER tester to the interface port(s) of one terminal, and either another BER tester or a
loopback plug to the corresponding interface port of the other terminal.
This BER test can be carried out over the Ethernet, E1/T1, V.24 or HSS interfaces. It will test the link
quality with regard to user payload data.
Caution: Do not apply signals greater than -20 dBm to the antenna as they can damage the receiver.
In a bench setup, there must be 60 - 80 dB at up to 2 GHz of 50 ohm coaxial attenuation (capable of
handling the transmit power) between the terminals’ antenna connectors.
In-service commissioning | 172
Additional tests
Depending on license requirements or your particular needs, you may need to carry out additional
tests, such as those listed below.
Refer to the relevant test equipment manuals for test details.
Test
Test equipment required
TX power output measurements (at TX and
duplexer outputs)
Power meter
TX spectrum bandwidth
Spectrum analyzer
TX spectral purity or harmonic outputs
Spectrum analyzer
TX center frequency
Frequency counter or spectrum analyzer
Bulk capacity BER test
BER tester
LAN throughput or errors
LAN tester
G.703 / HDB3 waveforms
Digital oscilloscope
Serial interface BER
BER tester
Audio quality
PCM4 or SINAD test set
In-service commissioning | 173
Checking the link performance
For a graphical indication of the link performance, you can use the constellation analyzer.
The 'dots' are a graphical indication of the quality of the demodulated signal. Small dots that are close
together indicate a good signal. If the dots become spaced further apart, this indicates that the signal
quality is degrading. This signal quality degradation can be caused by low Rx signal level due to, for
example:

external interference

failure of any of the following: modem, receiver, far end transmitter, an antenna (either end), a
feeder or connector (for example, due to water damage)

path issues such as multi-path fading or obstructions
To check the performance of the link using the constellation analyzer:
1. Select Link or Local or Remote > Performance > Constellation.
A blank constellation diagram appears:
2. Click Start to start the constellation analyzer.
While the constellation analyzer is running, the terminal will temporarily stop collecting error
performance statistics. If you want to run the constellation analyzer anyway, click OK when you
see this warning message:
3. Click Stop to stop the constellation analyzer.
The terminal automatically resumes collecting error performance statistics.
In-service commissioning | 174
Viewing a summary of the link performance
To view the performance summary for a terminal:
Select Link or Local or Remote > Performance > Summary.
Field
Explanation
Link Performance
Correctable errors
The total number of correctable blocks since the last reset
Uncorrectable errors
The total number of uncorrectable blocks since the last reset
SNR (dB)
The Signal to Noise Ratio of the link in dB
RSSI (dBm)
The Received Signal Strength Indication at the Rx input in dBm
Errored seconds
The total number of operational seconds with errored traffic since the last
reset
Error free seconds
The total number of error free operational seconds since the last reset
BER
The system will report an estimated Bit Error Rate up to a maximum of 1
x 10-12
TX temperature
The measured temperature in the transmitter module in °C
RX temperature
The measured temperature in the receiver module in °C
Ethernet performance
Transmitted packets
The total number of transmitted Ethernet packets
Received packets
The total number of received Ethernet packets
Received packet errors
The total number of packets received with errors
If you want to reset the error counters, click Reset Counters.
Maintenance | 175
13. Maintenance
There are no user-serviceable components within the terminal.
All hardware maintenance must be completed by 4RF or an authorized service centre.
Do not attempt to carry out repairs to any boards or parts.
Return all faulty terminals to 4RF or an authorized service centre.
For more information on maintenance and training, please contact Customer Services.
Caution: Electro Static Discharge (ESD) can damage or destroy the sensitive electrical components in
the terminal.
Routine maintenance
Every six or twelve months, for both ends of the link, you should record the RSSI and SNR levels as
well as checking the following:
Item
What to check or look for
Equipment shelter environment
Water leaks
Room temperature
Excessive vibration
Vermin damage
Terminal mounting
Firmly mounted
Antenna cable connections
Tight and dry
Antenna cable and its supports
Not loose or suffering from ultra-violet degradation
Antenna and its mounting hardware
Not loose, rusty or damaged
Safety earth
Connections tight
Cabling intact
DC system
Connections tight
Voltage in normal limits
Batteries (if installed)
Connections tight
Electrolyte levels normal
Maintenance | 176
Terminal upgrades
You can upgrade all software for both terminals remotely (through a management network), which
eliminates the need to physically visit either end of the link.
The best method of upgrading a terminal is to use the TFTP server method (see “Upgrading the
terminal using TFTP” on page 177). This method downloads all the required image files into the
terminal and then activates the correct files following a terminal reboot.
A terminal can also be upgraded by download all the required system software files (see “Upgrading
the terminal by uploading system files” on page 182”).
Upgrade process
To minimize disruption of link traffic and prevent your terminals from being rendered inoperative,
please follow the procedures described in this section together with any additional information or
instructions supplied with the upgrade package.
Before upgrading the terminal, ensure that you have saved the configuration file (see "Saving the
terminal's configuration" on page 66) as well as the cross connection configuration (see "Saving cross
connection configurations" on page 130).
The Remote terminal upgrade process will be faster if the bandwidth allocated to the management
ethernet capacity is maximized.
The terminal software must be identical at both ends of the link.
At the end of the terminal upgrade process, the versions of image files (kernel software, and firmware)
that were in use before the upgrade are still in the terminal. You can restore them, if required, by
editing the image tables and reactivating the old files (see “Changing the status of an image ” on page
188).
IMPORTANT NOTE: Ensure you are logged into the Near end terminal before you start an upgrade.
Installing RF synthesizer configuration files
If you are upgrading from software version 5_x_x or greater, refer to “Upgrading the terminal using
TFTP” on page 177).
If you are upgrading from a software version prior to 7_1_x, you will need to install new RF synthesizer
files, refer to “Configuration files” on page 182. You can then upgrade the terminal using TFTP (on
page 177).
Frequency Band
Synthesizer File(to be installed)
300 MHz
XE_300_400_synth.cfg
400 MHz
XE_300_400_synth.cfg
700 MHz
XE_600_700_800_900_synth.cfg
800 MHz
XE_600_700_800_900_synth.cfg
900 MHz
XE_600_700_800_900_synth.cfg
1400 MHz
XE_1400_synth.cfg
2000 MHz
XE_2000_2500_synth.cfg
2500 MHz
XE_2000_2500_synth.cfg
If you are upgrading from software version 3_x_x or 4_x_x, refer to “Upgrading the terminal by
uploading system files” on page 182.
Maintenance | 177
Upgrading the terminal using TFTP
Before upgrading the terminal, ensure that you have saved the configuration file (see "Saving the
terminal's configuration" on page 66) as well as the cross connection configuration (see "Saving cross
connection configurations" on page 130).
Upgrading the terminal using the TFTP (Trivial File Transfer Protocol) server involves these steps:
1. Run the TFTP server.
2. Login to the Near end terminal / local terminal (see “IP addressing of terminals” on page 47).
3. Run the TFTP upgrade process on the Remote terminal.
4. Reboot the Remote terminal.
5. Run the TFTP upgrade process on the Local terminal.
6. Reboot the Local terminal.
7. Clear the Java and web browser caches.
Step 1: Run the TFTP server
1. Double-click tftpd32.exe (located in the TFTPD directory) from the Aprisa CD supplied with the
product. Leave the TFTPD32 application running until the end of the upgrade process.
2. Click Settings and make sure that both SNTP server and DHCP server are not selected (no tick),
and click OK.
3. Click Browse and navigate to the root directory on the Aprisa CD (for example, D:\) supplied with
the product, then click OK.
4. Note down the IP address of the TFTP server (shown in the Server Interfaces drop-down list in the
TFTPD32 window) as you will need it later.
Maintenance | 178
Step 2: Log into the Local terminal
Use SuperVisor to log into the Near end terminal (now the Local terminal) (see “IP addressing of
terminals” on page 47) with either 'modify' or 'admin' privileges.
Step 3: Run the TFTP upgrade process on the Remote terminal
1. Select Remote > Maintenance > Upload > TFTP Upgrade.
2. Enter the IP address of the TFTP server (that you noted earlier)
3. Enter the version number of the software that you are upgrading to as a three digit number
separated by underscores, for example, 7_3_2.
4. Click Apply and check the TFTP server for download activity.
The Upgrade Result changes from 'Executing' to either 'Succeeded' or 'Failed'.
Note: This may take several minutes when upgrading the remote terminal.
If the upgrade has failed:

The TFTP server IP address may be set incorrectly

The 'Current Directory' on the TFTP server was not pointing to the location of the upload config
file e.g. 'Rel_7_3_2.cfg' .

There may not be enough free space in the image table to write the file. Inactive images can
be deleted (and the terminal rebooted) to free up space for the new image (see “Changing the
status of an image file” on page 188).
Step 4: Reboot the Remote terminal
Reboot the remote terminal before proceeding with the next step of the upgrade process (see
“Rebooting the terminal” on page 189).
1. Select Remote > Maintenance > Reboot and select [Hard Reboot]
Communications to SuperVisor remote page will fail until the remote terminal reboot has
completed.
Maintenance | 179
Step 5: Run the TFTP upgrade process on the Local terminal.
1. Select Local > Maintenance > Upload > TFTP Upgrade.
2. Enter the IP address of the TFTP server (that you noted earlier)
3. Enter the version number of the software (that you are upgrading to) for example, 7_3_2.
4. Click Apply and check the TFTP server for download activity.
The Upgrade Result changes from 'Executing' to either 'Succeeded' or 'Failed'.
Note: This may take several minutes when upgrading the remote terminal.
Step 6: Reboot the Local terminal
Reboot the local terminal before proceeding with the next step of the upgrade process (see “Rebooting
the terminal” on page 189).
1. Select Local > Maintenance > Reboot and select [Hard Reboot]
2. Log back into the Local terminal when the reboot has completed.
Step 7: Clear the Java and web browser caches
After upgrading the terminal you should clear the Java and web browser caches. The files stored in
them may cause the SuperVisor and Cross Connections applications to display incorrectly.
To clear the Java cache (Windows XP):
1. Select Start > Control Panel.
2. Select Java Plug-in
3. Click the Cache tab.
4. Click Clear and then click OK to confirm.
Maintenance | 180
To clear your web browser cache (Mozilla Firefox 1.x and above):
1. Select Tools > Options.
2. Select Privacy and then click Cache.
3. Click Clear to clear the cache, and then click OK to confirm.
Maintenance | 181
To clear your web browser cache (Internet Explorer 6.x and above):
1. Select Tools > Internet Options.
2. On the General tab, click Delete Files, and then click OK to confirm.
Maintenance | 182
Upgrading the terminal by uploading system files
A terminal can also be upgraded by uploading specific system files: configuration files, kernel image
files, software image files or firmware image files.
Note: You should only upgrade components that need changing. It is not always necessary, for
instance, to replace kernel or software files when upgrading a single firmware file. If interdependency
exists between file types, this will be made clear in the documentation that accompanied the update
package.
Configuration files
Configuration files (.cfg) are compressed archives containing a script to instruct the terminal on how to
handle the other files in the archive.
Uploading of configuration files can only be performed to the Local Terminal (not via the link to the
Remote Terminal).
RF synthesizer configuration files
The RF synthesizer configuration archive contains files that provide values for the transmitter and
receiver synthesizers to operate across the supported frequency bands.
Synthesizer configuration filenames have the following format:
XE_(frequency bands)_synth.cfg
e.g. XE_300_400_synth.cfg
Modem configuration files
The Modem configuration archive contains files that provide values for the Modem to operate at the
various supported channel sizes and modulation types.
Modem configuration filenames have the following format:
modem_(version number).cfg
e.g. modem_7_1_4.cfg
Cross-connect configuration files
The Cross-connect configuration archive contains the Cross Connections application program that can
be launched from within SuperVisor.
Cross-connect configuration filenames have the following format:
C-crossconnect_(version number).cfg
e.g. C-crossconnect_7_1_4.cfg
Maintenance | 183
To upload a configuration file:
1. Select Local > Maintenance > Config Files > Upload Configuration
2. Browse to the location of the file required to be uploaded into the terminal *.cfg.
3. Click on Upload.
The normal response is Succeeded if the file has been loaded correctly.
A response of ‘Failed’ could be caused by:
•
Not enough temporary space in the filesystem to uncompress the archive and execute the script
•
A file or directory expected by the script not being present on the filesystem
4. Reboot the terminal using a ‘Hard Reboot’ (see “Rebooting the terminal” on page 189).
Maintenance | 184
Image Files
Image files (.img) are loaded into the terminal and either contains code that is executed by the system
processor, or contain instructions to configure the various programmable logic elements. The image
file types that can be uploaded are:
•
Kernel image files
•
Software image files
•
Firmware image files
Note: The Bootloader image file C-CC-B-(version number).srec and Flash File System image file CCC-F-(version number).img can only be changed in the factory.
Uploading of image files can only be performed to the local terminal (not via the link to the remote
terminal).
To upload and activate an image file:
1. Upload the required image file.
If the Upload Status page show ‘executing’, then ‘writing to flash’, then ‘Succeeded’, then the file
has been written into the image table correctly.
If the Upload Status is ‘Failed’, there may not be enough free space in the image table to write the
file. Inactive images can be deleted (and the terminal rebooted) to free up space for the new
image (see “Changing the status of an image file” on page 188).
2. Set the status of the image to ‘activate’ (see “Changing the status of an image ” on page 188).
This actually sets the status to ‘Selected’ until after a terminal reboot.
3. Reboot the terminal using a ‘Hard Reboot’ (see “Rebooting the terminal” on page 189).
This activates the selected image. The image table status will now show ‘Active’.
The previous image file status will now show as ‘Inactive’.
Maintenance | 185
Kernel image files
Kernel image files contain code that forms the basis of the microprocessor’s operating system. There
can only ever be two kernel image files in the image table, the active and the inactive.
Kernel filenames have the following format:
C-CC-K-(version number).img
e.g. C-CC-K-7_1_4.img
To upload a kernel image file;
1. Select Local > Maintenance > Upload > Kernel
2. Browse to the location of the file required to be uploaded into the terminal *.img.
3. Click on Upload.
4. Activate the image (see “Changing the status of an image file” on page 188).
5. Reboot the terminal using a ‘Hard Reboot’ (see “Rebooting the terminal” on page 189).
Software image files
Software image files contain code that forms the basis of the terminal’s application and management
software (including the Web-based GUI). There can only ever be two software image files in the image
table, the active and the inactive.
Software image filenames have the following format:
C-CC-R-(version number).img
e.g. C-CC-R-7_1_4.img
To upload a software image file;
1. Select Local > Maintenance > Upload > Software
2. Browse to the location of the file required to be uploaded into the terminal *.img.
3. Click on Upload.
Software image files may take one or two minutes to upload as they can be quite large (≈ 2 Mbytes).
The size of this file has caused some Microsoft Internet Explorer proxy server setups to abort during
the software update process. To avoid this problem, either set the proxy file size limit to 'unlimited' or
avoid the use of the proxy altogether.
4. Activate the image (see “Changing the status of an image file” on page 188).
5. Reboot the terminal using a ‘Hard Reboot’ (see “Rebooting the terminal” on page 189).
Maintenance | 186
Firmware image files
Firmware image files contain instructions to configure the various programmable logic elements in the
terminal. There can only ever be two firmware image files for the same HSC version in the image
table, the active and the inactive.
Firmware image filenames have the following format:
C-fpga_Ef-x-y-z.img
e.g. C-fpga_E5-0-6-4.img
where f indicates the function (motherboard, interface card, etc).
Function Number
Function
Motherboard 1
Motherboard 2
QJET
Q4EM
DFXO
DFXS
Modem
QV24
HSS
where x indicates the HSC (hardware software compatibility) version.
Revision Number
Revision
revision A hardware
revision B hardware
revision C hardware
revision D hardware
where y indicates the firmware major revision number
where z indicates the firmware minor revision number
To upload a firmware image file;
1. Select Local > Maintenance > Upload > Firmware
2. Browse to the location of the file required to be uploaded into the terminal *.img.
3. Click on Upload.
4. Activate the image (see “Changing the status of an image file” on page 188).
5. Reboot the terminal using a ‘Hard Reboot’ (see “Rebooting the terminal” on page 189).
Maintenance | 187
Viewing the image table
To view the image table:
1. Select Link or Local or Remote > Maintenance > Image Table.
The image table shows the following information:
Heading
Function
Index
A reference number for the image file
Type
The image is not currently being used by the system and could be deleted.
Status
The status of the image; 'Active', 'Inactive', ‘Selected’, ‘Current (de-selected)’
Image Size
The image file size
Version
The image file name and version details
Note: Configuration file details do not appear in the image table.
Maintenance | 188
Changing the status of an image file
To change the status of an image:
1. Select Link or Local or Remote > Maintenance > Image Table.
2. Select the image you wish to change and click Edit.
3. On the Image Details, select the status from the Command drop-down list and click Apply.
Status
Function
Active
The image is currently being used by the system.
Inactive
The image is not currently being used by the system and could be deleted.
Selected
The image is not currently being used by the system but has been
activated and will become active following a terminal reboot.
Current (deselected)
The image is currently being used by the system but as another image has
been selected, it will become inactive following a terminal reboot.
Maintenance | 189
Rebooting the terminal
The local or remote terminals can be rebooted by SuperVisor.
You can specify a ‘Soft Reboot’ which reboots the terminal without affecting traffic or a ‘Hard Reboot’
which reboots the terminal (similar to power cycling the terminal).
You can specify an immediate reboot or setup a reboot to occur at a predetermined time.
To reboot the terminal:
1. Select Link or Local or Remote > Maintenance > Reboot.
2. Select the Reboot Type field:

None:
Do nothing.

Soft Reboot:
Reboots the software but should not affect customer traffic.

Hard Reboot:
Reboots the systems and affects customer traffic.
3. Select the Reboot Command field:

None:
Do nothing.

Reboot Now:
Execute the selected reboot now.

Timed Reboot:
Set the Reboot Time field to execute the selected reboot at a later date and time. This feature can
be used to schedule the resulting traffic outage for a time that has least customer impact.

Cancel Reboot:
Cancel a timed reboot.
4. Click Apply to execute the reboot or Reset to restore the previous configuration.
Maintenance | 190
Support summary
The support summary page lists key information about the terminal, for example, serial numbers,
software version, frequencies and so on.
To view the support summary:
Select Link or Local or Remote > Maintenance > Support Summary.
Maintenance | 191
Installing interface cards
Caution: You must power down the terminal before removing or installing interface cards.
Interface cards are initially installed in the factory to the customers’ requirements however, during the
life of the product, additional interface cards may need to be installed.
Unless the terminals are protected (see "Protected terminals" on page 163), installing new interface
cards involves a substantial interruption of traffic across the link. Staff performing this task must have
the appropriate level of education and experience; it should not be attempted by inexperienced
personnel.
To install an interface card:
1. Switch off the power to the terminal.
2. Prepare the terminal for new interface cards (see “Preparing the terminal for new interface cards”
on page 192).
3. Install the interface card (see “Installing an interface card” on page 194).
4. Power up the terminal.
5. Configure the slot (see “Configuring a slot” on page 196).
A slot can be configured before installing a new interface card, or after the interface card is
installed and the terminal power cycled.
6. Configure the cross connections. (see "Configuring the traffic cross connections" on page 133)
Maintenance | 192
Preparing the terminal for new interface cards
To prepare the terminal for a new interface card:
1. Remove the terminal from service by first switching off the terminal power. For an AC powered
terminal, remove the AC power connector. For a DC powered terminal, switch off the DC circuit
breaker or supply fuse.
2. Remove all other cables from the terminal, marking their locations first, if necessary, to aid later
restoration. The safety earth connection must be the last cable removed.
3. Ensure you have unobstructed access to the top and front of the terminal. Remove the terminal
from the equipment rack, if required.
4. Remove the top cover of the terminal by removing two socket screws from the rear.
Note: The top cover slides back towards the rear of the chassis.
5. Remove the front fascia by removing the four front panel socket screws.
Note: The front fascia first hinges out to clear the antenna connector and earth stud, and is then
removed by unclipping from the chassis and sliding downwards. See illustration below.
Maintenance | 193
6. Remove the card securing screw from the required interface slot.
7. There are two types of interface slot blanking plates, the seven tab break off and the single slot
type (newer type).
If the blanking plate is the seven tab break off, remove the slot blanking tab by folding the tab to
and fro until it breaks off.
If the blanking plate is the single slot type, unclip the blanking plate from behind the slot (assuming
that the card securing screw has already been removed).
Maintenance | 194
Installing an interface card
To install an interface card:
1. Remove the interface card from its packaging and static-safe bag.
Caution: To avoid static damage to the terminal or the interface card being installed, use a static
discharge wristband or similar antistatic device.
2. Offer the interface card into the chassis at an angle until the front panel of the card engages in the
chassis.
3. Rotate the card in the chassis until it is level, and both parts of the card interface bus connector
engage with the socket. Push down evenly on the interface card to seat it into the socket.
Maintenance | 195
4. Replace the card securing screw.
Note: Some interface cards may not have the bracket to accept the card securing screw.
5. Replace the fascia and top covers, restore all cables, and power up the terminal.
Maintenance | 196
Configuring a slot
1. Select Link or Local or Remote > Interface > Slot Summary.
2. Select the required slot and click Configure Slot.
'Slot' shows the slot the interface card is plugged into in the terminal (A – H).
Details of the interface card currently installed in the slot are:
'H/W’ (hardware revision).
'F/W’ (firmware revision)
'HSC’ (hardware software compatibility) A number used by the system software to determine
which FPGA ‘firmware image file’ to use in the interface card installed.
‘Installed’ field shows the actual interface card installed in the slot. If there is no interface card
installed in the slot, this field will show ‘none’.
‘Expected’ shows interface card type that had been previously installed. Interface cards can be
setup before they are installed in the terminal or after they are installed in the terminal.
3. To setup a new interface card in a slot, select the interface card type you want to fit (or has been
fitted) from the ‘Expected’ drop-down menu.
Note: The transmitter, receiver and modem are configured in other sections (see "Configuring the
terminal" on page 61).
4. Click Apply to apply changes or Reset to restore the previous configuration.
Troubleshooting | 197
14. Troubleshooting
Loopbacks
Loopbacks are used as a tool for testing or as part of the commissioning process and will affect
customer traffic across the link.
The terminal supports three types of loopbacks:

RF radio loopback

Interface loopbacks, set at the interface ports

Timeslot loopbacks
RF radio loopback
The RF radio loopback provides a loopback connection between the radio Tx and radio Rx. Each
terminal is looped back independently.
All traffic entering the transmit stage of the local terminal is turned around and delivered to the receiver
section. This loopback will affect all traffic through the terminal.
To enable or disable the RF loopback:
Select Link or Local or Remote > Maintenance > Loopbacks.

To enable the RF loopback, click the RF Loopback checkbox (tick the box).
Note: An RF loopback will automatically disable after the period set (in seconds) in the Loopback
Timeout field. The default entry is 3600 seconds (60 minutes).

To disable the RF loopback, click the RF Loopback checkbox (untick the box).
Click Apply to apply changes or Reset to restore the previous configuration.
Note: When the RF loopback is selected, both the RX and TX LEDs will flash.
Troubleshooting | 198
Interface loopbacks
The interface loopback provides a loopback connection for the customer-connected equipment. All
traffic arriving from the customer interface is looped back.
These loopbacks are applied on a port-by-port basis and can only be enabled on active ports i.e. has
to be activated by assigning traffic to it by the Cross Connections application.
The interface card green LED flashes while the loopback is active.
Loopback type
Description
QJET
(whole tributary)
The QJET interface loopback will loop back the selected E1 / T1 port.
QJET
(individual timeslot)
The Cross Connections application can loopback framed E1 / T1 timeslots
(see "Timeslot loopbacks” on page 198).
Q4EM port
The Q4EM interface loopback will loop back the port 4 wire analogue path
to the customer.
DFXO port
The DFXO interface loopback will loop back the port digital paths to return
the port analogue signal back to the customer.
DFXS port
The DFXS interface loopback will loop back the port digital paths to return
the port analogue signal back to the customer.
HSS port
The HSS interface loopback will loop back the port data to the customer.
QV24 port
The QV24 interface loopback will loop back the port data to the customer.
Ethernet
No loopback possible.
Timeslot loopbacks
You can loopback framed E1 / T1 timeslots in the Cross Connections application.
1. Open the Cross Connections application.
2. Right-click the timeslot you want to loop back.
3. Select Timeslot Loopback - the looped timeslot will display in black:
Troubleshooting | 199
Alarms
The LEDs (OK, RX, and TX) on the front panel illuminate either orange or red when there is a fault
condition:

Orange indicates a minor alarm that should not affect traffic across the link.

Red indicates a major alarm condition that could affect traffic across the link.
A major or minor alarm can be mapped to the external alarm outputs (see “Configuring the external
alarm outputs” on page 76).
Diagnosing alarms
To view the Alarm Summary and their current states:
Select Link or Local or Remote > Alarms > Summary.
Troubleshooting | 200
Alarm
Explanation
Synthesizer Status
The selected transmit frequency is outside the tuning range of the
transmitter synthesizer
Modem Lock
The terminal modem is not synchronized with the modem at the other end
of the link
TX Temp Shutdown
The transmitter power amplifier temperature is greater than 75°C. The
transmitter has shut down to prevent damage.
TX Temp Warning
The transmitter power amplifier temperature is greater than 70°C. The
transmitter will continue to operate in this condition, but if the power
amplifier temperature increases above 75°C, a major alarm condition is set
and the transmitter will shut down to prevent further damage.
TX AGC Voltage
The transmitter power amplifier automatic gain control is out of limits for
normal operation
TX Reverse Power
There is excessive reflected power at the transmitter port of the terminal,
indicating a low return loss in the path between transmitter port and the
antenna.
TX Return Loss
Status
Indicates the difference between the transmitted power and the amount of
power being reflected back into the terminal. The alarm will trigger when
there is too much reflected power from the antenna that will degrade link
performance.
RX RSSI
The RX RSSI alarm threshold is determined by the RSSI Thresholds for
each of the modulation types (see “Configuring the RSSI alarm threshold”
on page 73)
Fan 1
The internal cooling fan 1 is not operating
Fan 2
The internal cooling fan 2 is not operating
External Input 1 -2
Indicates an active alarm state on the the external alarm input
Alarm Output 1 - 4
Indicates an active alarm state on the the external alarm output
MHSB Switch
Indicates that the MHSB has switched over. The MHSB alarm is only shown
if MHSB mode is enabled (see “Configuring the terminals for MHSB” on
page 160).
To view detailed alarm information:
Select Link or Local or Remote > Alarms > Alarm Table
The Alarm Table shows the source of the alarm and the type, the slot (and port, if applicable) where
the alarm originated, the severity and the date and time the alarm occurred.
To further diagnose the cause of the alarm (see “Identifying causes of alarms” on page 204, and
“Alarm types” on page 229).
Troubleshooting | 201
Viewing the alarm history
The alarm history page shows the historical alarm activity for up to 50 alarms. This page refreshes
every 30 seconds.
To view the alarm history:
Select Link or Local or Remote > Alarms > Alarm History.
Field
Explanation
Source
The component within the terminal that generated the alarm
Type
The type of alarm (see "Alarm types and sources" on page 229)
Slot
The slot where the alarm originated, if applicable
Port
The port where the alarm originated, if applicable
Severity
Whether the alarm was a major or minor alarm
Status
Whether the alarm is active or cleared
Time
The date and time when the alarm occurred
To clear the alarm history:
Select Local or Remote > Alarms > Clear History
The alarm history for up to 100 alarms can be seen using SNMP (see “SNMP (Simple Network
Management Protocol)” on page 67).
Troubleshooting | 202
Viewing interface alarms
To view the alarms for a particular interface:
1. Select Link or Local or Remote > Interface > Interface Summary.
2. Select the desired interface card slot from the Interface Summary and click Alarms.
This opens a page as shown below with a summary of the alarms on the interface card:
The following fields are displayed:

Source: The type of interface card that generated the alarm

Type: The type of interface alarm

Slot: The slot of the interface card that generated the interface alarm

Port: The port that generated the interface alarm

Severity: Whether the interface alarm was major or minor
3. Return to the Interface Summary page by either selecting Options > Interface Summary or clicking
Back in the browser window.
Troubleshooting | 203
Clearing alarms
Select Link or Local or Remote > Alarms > Clear Alarms
MHSB Command
If a MHSB switchover event occurs, the OK LED on the front panel changes to orange.
To clear the MHSB switchover alarm:
Select Clear Switched Alarm from the MHSB Command drop-down list and click on Apply.
Image Table Alarm
An image table alarm appears if a problem occurred during the boot process which may have left the
image table in an inconsistent state.
To clear the two types of image table alarms:

The alternate image table alarm: this indicates that a backup image table has been used. This will
match the actual image table unless immediately following a software upgrade.

The default image table alarm: this indicates that the image table has been rebuilt from defaults. In
some circumstances this will mean that an incorrect build of software is running on the terminal.
In either case, in addition to clearing the image table alarm, you should verify that the active images in
the image table are correct for their software release.
Troubleshooting | 204
Identifying causes of alarms
The following are possible causes of an alarm.
LED
Colour
Possible causes
OK
Orange
A minor system alarm is set
Red
A major system alarm is set
Orange
Low RSSI or AGC limits have been exceeded
Red
Receiver power supply or synthesizer failure
Orange
AGC, transmitter temperature, forward power or reverse power limits have
been exceeded
Red
Transmit power supply or synthesizer failure
RX
TX
OK LED
Colour
Alarm condition
Suggested action
Orange
Fan failure
Check that the fans are not blocked and can spin freely.
Orange
Interface card
mismatch
Using SuperVisor, check that the expected interface card and the
fitted interface card are the same.
Red
Modem lock
A modem lock alarm is generally seen when other conditions such
as low RSSI are present. If there are no other alarms indicated,
check the following:
The terminal clocking is set up correctly.
Both terminals are using the same modulation.
Both terminals are using the same version of software.
External RF Interference from equipment operating in adjacent
channels.
Check the constellation pattern for evidence of disturbances in the
RF path.
Compare RSSI with the expected values from the original path
engineering calculation. Investigate any large differences.
If the fault persists, contact your local representative.
Red
Interface alarms
Check that the E1 or Ethernet interface cables are fitted correctly
and the equipment they are connected to is functioning correctly.
Troubleshooting | 205
RX LED
Colour
Alarm condition
Suggested action
Orange
Low RSSI
Check that all antenna and feeder cables are firmly connected
and not damaged or kinked
Check there is no damage to the antenna
Check the TX power and alarm status of the remote terminal
Orange
Receiver AGC
Contact your local 4RF representative
Red
Receiver power
supply
Contact your local 4RF representative
Colour
Alarm condition
Suggested action
Orange
Reverse power
Check that all antenna and feeder cables are firmly connected
and not damaged or kinked
Check there is no damage to the antenna
Check that the Receiver and Transmitter ports are correctly
connected to the High and Low ports of the duplexer
Red
Transmitter
temperature
Check operation of cooling fan or fans
Ensure the air grills on the sides of the terminal are clear
Ensure the ambient air temperature around the equipment is less
than 50˚C
TX LED
Troubleshooting | 206
E1 / T1 alarm conditions
The QJET interface yellow LED indicates:

Loss of signal (LOS)
A loss of signal alarm occurs when there is no valid G.703 signal at the E1 / T1 interface RX input
from the downstream system.
This alarm masks the LOF and AIS received alarms.

Loss Of Frame alignment (LOF)
A loss of frame alignment alarm occurs when the E1 / T1 interface RX input receives a valid G.703
signal (code and frequency) but does not receive a valid G.704 signal i.e. no frame alignment
word, from the downstream system (in framed E1 / T1 modes only) (red alarm in framed T1
modes).
This alarm masks the AIS received alarm.

Alarm Indication Signal (AIS)
An AIS received alarm occurs when AIS is received from the downstream system.
An E1 / T1 interface will output AIS to the downstream system if the normal upstream traffic signal
is not available e.g. loss of modem synchronization, loss of RF signal across the link (blue alarm in
framed T1 modes).

Remote Alarm Indicator (RAI)
A remote alarm indicator occurs when RAI is received from the downstream system when it has
an active LOS or LOF alarm (TS0 NFAS bit 3 in framed E1 modes and yellow alarm in framed T1
modes).

TS16 Loss of signal (TS16LOS)
A TS16 loss of signal alarm occurs when there is no valid TS16 signal at the E1 interface RX input
from the downstream system (in E1 PCM 30 modes only).

TS16 Remote Multi-frame Alarm Indicator (RMAI)
A remote multiframe alarm indicator occurs when RMAI is received from the downstream system
when it has an active TS16LOS alarm (TS16 F0 bit 6 in E1 PCM 30 modes only).

TS16 Alarm Indication Signal (TS16AIS)
A TS16 Alarm Indication Signal alarm occurs when AIS is received from the downstream system
in TS16.
An E1 interface will output the TS16 AIS signal to the downstream system if the normal TS16
multi-frame signal is not available (in E1 PCM 30 modes only).
The QJET interface green LED indicates:
The QJET interface green LED flashes when the E1 / T1 port loopback is active.
Troubleshooting | 207
System log
SuperVisor automatically keeps a log, known as 'syslog', which captures all alarms, errors and events
for each terminal.
You can specify that the ‘syslog’ is saved to a particular file (see "Setting up for remote logging” on
page 209). You can then email this file to customer service, if requested, to enable them to fault-find
more accurately.
Checking the syslog
To view the Syslog:
1. Select Local > Performance > Logging > Syslog.
This opens a new window:
Troubleshooting | 208
2. The system log is quite hard to decipher in Internet Explorer. If you're using Internet Explorer,
select View > Source, which opens the file in a more legible layout in Notepad (see illustration
below). Save or print this file, as required.
3. If you want to save the system log, you can save it from within Notepad (or Internet Explorer).
Select File > Save As. Navigate to where you want to save the file. Enter a meaningful filename
and select 'Text File' from the Save As Type drop-down list. Click Save.
You can specify that this file is automatically saved to a computer (see "Setting up for remote logging”
on page 209).
Troubleshooting | 209
Setting up for remote logging
Note: When setting up to save the system log to a specific computer, be aware that the file is
constantly updated and may get quite large quite quickly.
To set up a terminal for remote logging:
1. Copy the TFTP server application (tftpd32.exe, which is located in the TFTPD directory) from the
terminal product CD into a suitable directory on the PC (for example, C:\Program Files\TFTP
Server).
2. Create another directory where you want the system logs to be saved for example;
C:\Aprisa XE Syslog
3. Double-click tftpd32.exe.
4. Click Settings and make sure that both ‘Syslog Server’ and ‘Save syslog message’ boxes are
ticked.
5. Click Browse and select a directory where you want the Syslog file to be saved (created in step 2).
6. Click OK to close the Settings dialog box.
Troubleshooting | 210
7. In SuperVisor, select Link or Link or Local or Remote > Terminal > Advanced.
8. In the Remote Syslog Address field, enter the IP address of the PC on which the Syslog server is
running.
9. In the Remote Syslog Port field, enter 514.
10. Reboot the terminal (Link or Local or Remote > Maintenance > Reboot).
11. Open the directory where the system logs are being saved to. You should see a file called
syslog.txt.
Interface connections | 211
15. Interface connections
RJ-45 connector pin assignments
RJ-45 pin numbering
Interface traffic direction
All interface traffic directions and labels used in this manual refer to the direction relative to the
terminal. Refer to the diagram below.
The traffic direction describes the transmit / receive paths and the direction of handshaking and
clocking signals, depending on the interface.
Interface connections | 212
QJET Interface connections
Pin
number
Pin function
Direction
TIA-568A wire
colour
Transmit
Output
Green/white
Transmit
Output
Green
Not used
Receive
Input
Blue
Receive
Input
Blue/white
Not used
Orange
Not used
Brown/white
Not used
Brown
Orange/white
RJ-45 connector LED indicators
LED
Status
Explanation
Green
On
Normal operation
Yellow
On
Loss of signal (LOS) or
Alarm Indication Signal (AIS) or
Loss Of Frame alignment (LOF) in Framed
modes
Green
Flashing
Port in loopback
The standard QJET interface is 120 ohm balanced.
External Balun transformers can be used to provide a 75 ohm unbalanced interface.
Interface connections | 213
Ethernet interface connections
Pin
number
Pin function
Direction
TIA-568A wire
colour
Transmit
Output
Green/white
Transmit
Output
Green
Receive
Input
Orange/white
Not used
Blue
Not used
Blue/white
Receive
Not used
Brown/white
Not used
Brown
Input
RJ-45 connector LED indicators
LED
Status
Explanation
Green
On
Ethernet activity
Orange
Interface connections | 214
Q4EM Interface connections
Pin
number
Pin function
Direction
TIA-568A wire
colour
Input
Green/white
M1
Input
Green
Receive (Ra/R)
Input
Orange/white
Transmit (Tb/R1)
Output
Blue
Transmit (Ta/T1)
Output
Blue/white
Receive (Rb/T)
Input
Orange
Output
Brown/white
E1
Output
Brown
RJ-45 connector LED indicators
LED
Status
Explanation
Green
On
Normal operation (M signal)
Yellow
On
Alarm condition (E signal)
Green
Flashing
Port in loopback
Interface connections | 215
E&M Signalling types
The Q4EM E&M signalling leads are optically isolated, bi-directional lines which can be externally
referenced to meet any of the EIA-464 connection types I, II,IV or V (as shown below).
The M1 lead associated with the M wire detector can be externally referenced to earth or battery as
required.
The E1 lead associated with the E wire output can be externally referenced to earth or battery as
required.
Interface connections | 216
Interface connections | 217
DFXS Interface connections
The subscriber interface connects the terminal to the customer's 2 wire
telephone via a 2 wire line.
Each 2 wire channel has two access points: one connects to a customer; the
other is a local test port.
Warning: If there is a power failure at either terminal, any
telephone connected at the DFXS will not operate.
Please ensure that a separate telephone that is not
dependent on local power is available for use in an
emergency.
RJ-45
Pin number
Pin function
Direction
Not used
Green/white
Not used
Green
Not used
Orange/white
Ring
Bi-directional
Blue
Tip
Bi-directional
Blue/white
Not used
Orange
Not used
Brown/white
Not used
Brown
RJ-45 connector LED indicators
LED
Status
Explanation
Green
On
Normal operation
Yellow
Flashing
Loopback in place
Yellow
On
Alarm condition
Both LEDs
Flashing
Loss of CAS signals
TIA-568A wire
colour
Interface connections | 218
DFXO Interface connections
The DFXO interface connects the terminal to the telephone network via a 2 wire
line.
Each DFXO channel has two access points: one connects to a customer; the
other is a local test port.
RJ-45
Pin number
Pin function
Direction
Not used
Green/white
Not used
Green
Not used
Orange/white
Ring
Bi-directional
Blue
Tip
Bi-directional
Blue/white
Not used
Orange
Not used
Brown/white
Not used
Brown
RJ-45 connector LED indicators
LED
Status
Explanation
Green
On
Normal operation
Yellow
Flashing
Loopback in place
Yellow
On
Alarm condition
TIA-568A wire
colour
Interface connections | 219
HSS Interface connections
The connector on the high-speed synchronous serial interface is a high density
LFH-60 (as used on standard Cisco WAN port serial interface cables and
equivalents).
The interface specification (X.21 / V.35 etc) is automatically changed by simply
changing the type of interface cable connected to the HSS.
LED indicators
LED
Status
Explanation
Top green LED
On
Normal operation
Top green LED
Flashing
Loopback in place
Lower green LED
On
Normal operation
Interface connections | 220
Synchronous cable assemblies
Sync EIA/TIA-232 for DTE (Part number: Cab Sync 232MT)
Pin number
Pin function
Direction
Ground
TXD
Input
RXD
Output
RTS
Input
CTS
Output
DSR
Output
Circuit DCD
DCD
Output
15
TXC
Output
17
RXC
Output
18
LTST
Input
20
DTR
Input
24
TXCE
Input
Sync EIA/TIA-232 Cable Assembly for DCE (Part number: Cab Sync 232FC)
Pin number
Pin function
Direction
GND
TXD
Output
RXD
Input
RTS
Output
CTS
Input
DSR
Input
Circuit Ground
DCD
Input
15
TXC
Input
17
RXC
Input
18
LTST
Output
20
DTR
Output
24
TXCE
Output
Interface connections | 221
EIA/TIA-449 Serial Cable Assembly for DTE (Part number: Cab Sync 449MT)
Pin number
Pin function
Direction
Shield Ground
22
SD+
SD-
Input
Input
23
ST+
ST-
Output
Output
24
RD+
RD-
Output
Output
25
RS+
RS-
Input
Input
26
RT+
RT-
Output
Output
27
CS+
CS-
Output
Output
10
37
LL
SC
Input
11
29
DM+
DM-
Output
Output
12
30
TR+
TR-
Input
Input
13
31
RR+
RR-
Output
Output
17
35
TT+
TT-
Input
Input
19
20
SG
RC
Interface connections | 222
EIA/TIA-449 Serial Cable Assembly for DCE (Part number: Cab Sync 449FC)
Pin number
Pin function
Direction
Shield Ground
22
SD+
SD-
Output
Output
23
ST+
ST-
Input
Input
24
RD+
RD-
Input
Input
25
RS+
RS-
Output
Output
26
RT+
RT-
Input
Input
27
CS+
CS-
Input
Input
10
37
LL
SC
Output
11
29
DM+
DM-
Input
Input
12
30
TR+
TR-
Output
Output
13
31
RR+
RR-
Input
Input
17
35
TT+
TT-
Output
Output
19
20
SG
RC
Interface connections | 223
V.35 Serial Cable Assembly for DTE (Part number: Cab Sync V35MT)
Pin number
Pin function
Direction
Frame Ground
Circuit Ground
RTS
Input
CTS
Output
DSR
Output
RLSD
Output
DTR
Input
LT
Input
SD+
SD-
Input
Input
RD+
RD-
Output
Output
SCTE+
SCTE-
Input
Input
SCR+
SCR-
Output
Output
AA
SCT+
SCT-
Output
Output
V.35 Serial Cable Assembly for DCE (Part number: Cab Sync V35FC)
Pin number
Pin function
Direction
Frame Ground
Circuit Ground
RTS
Output
CTS
Input
DSR
Input
RLSD
Input
DTR
Output
LT
Output
SD+
SD-
Output
Output
RD+
RD-
Input
Input
SCTE+
SCTE-
Output
Output
SCR+
SCR-
Input
Input
AA
SCT+
SCT-
Input
Input
Interface connections | 224
X.21 Serial Cable Assembly for DTE (Part number: Cab Sync X21MT)
Pin number
Pin function
Direction
Shield Ground
Transmit+
Transmit-
Input
Input
10
Control+
Control-
Input
Input
11
Receive+
Receive-
Output
Output
12
Indication+
Indication-
Output
Output
13
Timing+
Timing-
Output
Output
Circuit Ground
X.21 Serial Cable Assembly for DCE (Part number: Cab Sync X21FC)
Pin number
Pin function
Direction
Shield Ground
Transmit+
Transmit-
Output
Output
10
Control+
Control-
Output
Output
11
Receive+
Receive-
Input
Input
12
Indication+
Indication-
Input
Input
13
Timing+
Timing-
Input
Input
Circuit Ground
Interface connections | 225
EIA-530 Serial Cable Assembly for DCE (Part number: Cab Sync 530FC)
Pin number
Pin function
Direction
14
BA(A), TXD+
BA(B), TXD-
Output
Output
16
BB(A), RXD+
BB(B), RXD-
Output
Outputcc
19
CA(A), RTS+
CA(B), RTS-
Output
Output
13
CB(A), CTS+
CB(B), CTS-
Input
Input
22
CC(A), DSR+
CC(B), DSR-
Input
Input
Shield
10
CF(A), DCD+
CF(B), DCD-
Input
Input
15
12
DB(A), TXC+
DB(B), TXC-
Input
Input
17
DD(A), RXC+
DD(B), RXC-
Input
Input
18
LL
Circuit Ground
Output
20
23
CD(A), DTR+
CD(B), DTR-
Output
Output
24
11
DA(A), TXCE+
DA(B), TXCE-
Output
Output
25
TM, not used
Output
Interface connections | 226
EIA-530 Serial Cable Assembly for DTE (Part number: Cab Sync 530MT)
Pin number
Pin function
Direction
14
BA(A), TXD+
BA(B), TXD-
Input
Input
16
BB(A), RXD+
BB(B), RXD-
Output
Output
19
CA(A), RTS+
CA(B), RTS-
Input
Input
13
CB(A), CTS+
CB(B), CTS-
Output
Output
22
CC(A), DSR+
CC(B), DSR-
Output
Output
Shield
10
CF(A), DCD+
CF(B), DCD-
Output
Output
15
12
DB(A), TXC+
DB(B), TXC-
Output
Output
17
DD(A), RXC+
DD(B), RXC-
Output
Output
18
LL
Circuit Ground
Input
20
23
CD(A), DTR+
CD(B), DTR-
Input
Input
24
11
DA(A), TXCE+
DA(B), TXCE-
Input
Input
25
TM, not used
Input
Interface connections | 227
Cable WAN connectors
Cisco LFH-60
cable name
WAN connector
Connector gender
Label on WAN end
232FC
DB-25
female
'to DTE'
232MT
DB-25
male
'to DCE'
449FC
DB-37
female
'to DTE'
449MT
DB-37
male
'to DCE'
V35FC
M34
female
'to DTE'
V35MT
M34
male
'to DCE'
X21FC
DB-15
female
'to DTE'
X21MT
DB-15
male
'to DCE'
530FC
DB-25
female
'to DTE'
530MT
DB-25
male
'to DCE'
Interface connections | 228
QV24 Interface connections
Pin number
Pin function
Direction
TIA-568A wire
colour
RTS
Input
Green / white
DTR
Input
Green
TXD
Input
Orange / white
Ground
DCD / Ground
Input
Blue / white
RXD
Output
Orange
DSR
Output
Brown / white
CTS
Output
Brown
Blue
RJ-45 connector LED indicators
LED
Status
Explanation
Green
On / flashing
Transmit data
Yellow
On / flashing
Receive data
Alarm types and sources | 229
16. Alarm types and sources
Alarm types
Note: If you need to contact customer support about any of these alarms, please supply the reference
number.
Transmitter alarms
Ref
Type
Explanation
A1
txADCChZeroHi
The transmitter AGC voltage is high
A2
txADCChZeroLo
The transmitter AGC voltage is low
A3
txADCChOneHi
The transmitter Forward Power Monitor reading is high
A4
txADCChOneLo
The transmitter Forward Power Monitor reading is low
A5
txADCChTwoHi
The transmitter Reverse Power Monitor reading is high
A6
txADCChTwoLo
The transmitter Reverse Power Monitor reading is low
A7
txADCChThreeHi
The transmitter temperature is greater than 75°C and the
transmitter has shut down
A8
txADCChElevenHi
The transmitter temperature is greater than 70°C.
A9
txADCChFourHi
The transmitter synthesizer tuning voltage is high
A10
txADCChFourLo
The transmitter synthesizer tuning voltage is low
A11
txADCChSevenHi
The transmitter digital 5 VDC power supply voltage is high
A12
txADCChSevenLo
The transmitter digital 5 VDC power supply voltage is low
A13
txADCChEightHi
The transmitter reference 7 VDC power supply voltage is high
A14
txADCChEightLo
The transmitter reference 7 VDC power supply voltage is low
A15
txADCChNineHi
The transmitter 9 VDC power supply voltage is high
A16
txADCChNineLo
The transmitter 9 VDC power supply voltage is low
A17
txADCChSixHi
The transmitter 11 VDC power supply voltage is high
A18
txADCChSixLo
The transmitter 11 VDC power supply voltage is low
A19
txADCChFiveHi
The transmitter 28 VDC power supply voltage is high
A20
txADCChFiveLo
The transmitter 28 VDC power supply voltage is low
A21
txSynthLD
The transmitter synthesizer frequency is not set
A22
tx5VFail
The transmitter 5 VDC power supply has failed
A23
tx11VFail
The transmitter 11 VDC power supply has failed
A24
tx28VFail
The transmitter 28 VDC power supply has failed
A25
txEEFail
The transmitter on-board memory has failed
A26
txTSensorFail
The transmitter temperature sensor has failed
A27
txReturnLoss
The transmitter return loss is high
A28
txAmplifierBalance
One side of the transmitter amplifier has failed
A29
txMibFail
The transmitter MIB is corrupt in EEPROM
A30
txADCChSixHi
The transmitter VCO voltage is high
A31
txADCChSixLo
The transmitter VCO voltage is low
A32
txADCChEightHi
The transmitter digital -5 VDC power supply voltage is high
A33
txADCChEightLo
The transmitter digital -5 VDC power supply voltage is low
Alarm types and sources | 230
Receiver alarms
Ref
Type
Explanation
B1
rxADCChEightHi
The AGC voltage is high
B2
rxADCChEightLo
The AGC voltage is low
B3
rxRSSIHi
The receiver maximum input level has been exceeded
B4
rxRSSILo
The RSSI is below the alarm threshold setting (see page 73)
B5
rxADCChSixHi
The synthesizer tuning voltage is high
B6
rxADCChSixLo
The synthesizer tuning voltage is low
B7
rxADCChSevenHi
The -1.5 VDC power supply is high
B8
rxADCChSevenLo
The -1.5 VDC power supply is low
B9
rxADCChTwoHi
The 3.3 VDC power supply is high
B10
rxADCChTwoLo
The 3.3 VDC power supply is low
B11
rxADCChOneHi
The digital 5 VDC power supply voltage is high
B12
rxADCChOneLo
The digital 5 VDC power supply voltage is low
B13
rxADCChZeroHi
The 9 VDC power supply voltage is high
B14
rxADCChZeroLo
The 9 VDC power supply voltage is low
B15
rx12VFail
The 12 VDC power supply has failed
B16
rxSynthLD
The synthesizer frequency is not set
B17
rxEEFail
The on-board memory has failed
B18
rxADCChNineHi
The 28 VDC power supply voltage is high
B19
rxADCChNineLo
The 28 VDC power supply voltage is low
B20
rxOff
The receiver is off
B21
rxADCChFiveHi
The receiver temperature is too high
B22
rxMibFail
The receiver MIB is corrupt in EEPROM
MUX alarms
Ref
Type
Explanation
C1
muxInit
A MUX card failed to program
C2
muxMibEEFail
The MIB EEROM is corrupt
C3
muxCharEEFail
The character data is corrupt
Modem alarms
Ref
Type
Explanation
D1
mdLOS
The modem has loss of synchronization with the far end
D2
mdDemodAlignmentLost
The modem is unable to synchronize to the payload framing
D3
mdTdmAlignmentLost
The modem is unable to synchronize to the system bus timing
D4
mdRefAFail
The modem reference clock A has failed
D5
mdRefBFail
The modem reference clock B has failed
D6
mdClkSyncFail
The modem is unable to synchronize to the system clock
D7
mdEEFail
The modem EEPROM is corrupt
Alarm types and sources | 231
Motherboard alarms
Ref
Type
Explanation
E1
mbFan1Fail
Fan 1 failure
E2
mbFan2Fail
Fan 2 failure
E3
mbCardMismatch
The expected interface card is different to the card that is
fitted
E4
mbHwHsc
A MUX card has an unsupported HSC number
QJET alarms
Ref
Type
Explanation
F1
e1AIS
The E1 interface RX input has received an Alarm Indication
Signal from the downstream equipment.
F2
e1RAI
The E1 interface interface RX input has received a Remote
Alarm Indication alarm (RAI) from the downstream equipment.
A remote alarm indicator signal is sent from the downstream
equipment when it has an active LOS or LOF alarm.
F3
e1LOS
The E1 interface Loss Of Signal alarm (LOS)
F4
e1CRC4
The E1 interface Cyclic Redundancy Check 4 alarm indicates
a loss of or corrupted CRC data.
F5
e1LOF
The E1 interface Loss Of Frame alignment (LOF)
F6
e1RMAI
The E1 interface interface RX input has received an RMAI
from the downstream equipment.
A TS16 remote alarm indicator signal is sent from the
downstream equipment when it has an active TS16 LOS or
LOF alarm.
F7
e1TS16AIS
The E1 interface RX input has received a TS16 Alarm
Indication Signal from the downstream equipment.
F8
e1TS16LOS
The E1 timeslot 16 Loss Of Signal alarm
F9
t1AIS
The T1 interface RX input has received an Alarm Indication
Signal from the downstream equipment (AIS Received alarm)
F10
t1RAI
The T1 interface interface RX input has received a Remote
Alarm Indication alarm (RAI) from the downstream equipment.
F11
t1LOS
The T1 interface Loss Of Signal alarm (LOS)
F12
t1LOF
The T1 interface Loss Of Frame alignment (LOF)
Alarm types and sources | 232
DFXO alarms
Ref
Type
Explanation
G1
fxoCodecOvld
Codec receive signal overload detected
G2
fxoBillToneOvld
Billing tone overload detected
G3
fxoUnplug
Exchange line unplugged from interface
G4
fxoCurrentOvld
Loop current overload detected (greater than 100 mA)
DFXS alarms
Ref
Type
Explanation
H1
fxsCalibError
The phone was off-hook during the initialization phase
H2
fxsDCDCError
DC-DC converter low battery voltage error
H3
fxsCasLock
Loss of CAS lock
HSS alarms
Ref
Type
Explanation
J1
hssLoss
Loss of control pattern
J2
hssRxFifoFull
HSS RX FIFO overrun
J3
hssRxFifoEmpty
HSS RX FIFO underrun
J4
hssTxFifoFull
HSS TX FIFO overrun
J5
hssTxFifoEmpty
HSS TX FIFO underrun
J6
hssRxClockInvalid
The RX clock is invalid
J7
hssTxClockInvalid
The TX clock is invalid
QV24 alarms
Ref
Type
Explanation
K1
v24CtrlLineLoss
The V.24 control lines are not in sync
Alarm types and sources | 233
External alarm inputs
Ref
Type
Explanation
L1
externalAlarm1
There has been an alarm on external alarm input 1
L2
externalAlarm2
There has been an alarm on external alarm input 2
Remote terminal alarms
Ref
Type
Explanation
M1
remoteMajorAlarm
There has been a major alarm on the remote terminal
M2
remoteMinorAlarm
There has been a minor alarm on the remote terminal
Cross connect alarms
Ref
Type
Explanation
N1
ccNoBandwidth
There is insufficient bandwidth for the current cross
connection configuration
MHSB alarms
Ref
Type
Explanation
P1
mhsbSwitchToStandby
The terminal has switched from active to standby
Country specific settings | 235
17. Country specific settings
The following table shows the country-specific settings for the DFXO / DFXS interface cards. If the
country you want is not listed, contact the local telephone company for assistance.
Country
DFXO / DFXS Termination / balance
impedance
DFXO
loop
current
limiter
DFXO
on-hook
speed
DFXO
ringing
impedance
DFXO
ringing
detection
threshold
Argentina
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Australia
TN12 220Ω + (820Ω ║ 120nF)
On
26 ms
> 10 MΩ
16 Vrms
Austria
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Bahrain
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Belgium
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Brazil
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Bulgaria
220Ω + (820Ω ║ 120nF)
On
3 ms
> 10 MΩ
16 Vrms
Canada
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Chile
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
China
600Ω and
China 200Ω + (680Ω ║ 100nF)
On
< 500 μs
> 10 MΩ
16 Vrms
Colombia
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Croatia
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Cyprus
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Czech Republic
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Denmark
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Ecuador
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Egypt
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
El Salvador
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Finland
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
France
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Germany
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Greece
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Guam
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Hong Kong
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Hungary
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Iceland
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
India
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Indonesia
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Ireland
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Israel
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Italy
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Japan
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Jordan
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Kazakhstan
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Kuwait
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Latvia
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Lebanon
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Luxembourg
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Country specific settings | 236
Macao
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Malaysia
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Malta
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Mexico
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Morocco
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Netherlands
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
New Zealand
BT3 (370Ω + (620Ω ║ 310nF))
On
< 500 μs
> 10 MΩ
16 Vrms
Nigeria
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Norway
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Oman
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Pakistan
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Peru
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Philippines
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Poland
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Portugal
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Romania
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Russia
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Saudi Arabia
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Singapore
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Slovakia
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Slovenia
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
South Africa
TBR21 270Ω + (750Ω ║ 150nF)
On
< 500 μs
30 kΩ
16 Vrms
South Korea
600Ω
On
< 500 μs
30 kΩ
16 Vrms
Spain
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Sweden
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Switzerland
TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
Taiwan
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Thailand
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
UAE
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
UK
BT Network 320Ω + (1050Ω ║ 230nF)
and TBR21 270Ω + (750Ω ║ 150nF)
On
3 ms
> 10 MΩ
16 Vrms
USA
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Yemen
600Ω
On
< 500 μs
> 10 MΩ
16 Vrms
Specifications | 237
18. Specifications
RF specifications
Frequency Bands ETSI R1
Frequency Bands FCC R1
Frequency
Band
300 MHz band
Frequency
Band Limits
330 - 400 MHz
Synthesizer
Step Size
6.25 kHz
400 MHz band
400 - 470 MHz
6.25 kHz
600 MHz band
620 - 715 MHz
12.5 kHz
700 MHz band
698 - 806 MHz
25 kHz
800 MHz band
805 - 890 MHz
25 kHz
900 MHz band
850 - 960 MHz
25 kHz
1400 MHz band
1350 - 1550 MHz
12.5 kHz
2000 MHz band
1900 - 2300 MHz
62.5 kHz
2500 MHz band
2300 - 2700 MHz
62.5 kHz
Frequency
Band
400 MHz band
Frequency
Band Limits
330 - 512 MHz
Synthesizer
Step Size
6.25 kHz
900 MHz band
850 - 960 MHz
25 kHz
Modulation
16 / 32 / 64 QAM and QPSK (s oftware configurable)
Frequency stability
±3 ppm
Antenna connector
N-type fem ale 50 Ω
Note R1
Contact 4RF for other frequency options
Specifications | 238
System performance specifications
Capacity ETSI C2
Channel size
25 kHz
C3
50 kHz C3
QPSK
Gros s
150 kHz
C4
200 kHz C5
48 kbit/s
168 kbit/s
208 kbit/s
256 kbit/s
Gros s
Gros s
16 kbit/s
0 kbit/s
312 kbit/s
400 kbit/s
16 kbit/s
264 kbit/s
536 kbit/s
672 kbit/s
808 kbit/s
Gros s
6 tim es lots
4 tim eslots
10 tim es lots
12 tim es lots
Ways ide
8 kbit/s
24 kbit/s
32 kbit/s
40 kbit/s
336 kbit/s
680 kbit/s
840 kbit/s
Gros s
5 tim eslots
8 tim eslots
4 tim es lots
E1
10 tim eslots
13 tim es lots
16 kbit/s
40 kbit/s
8 kbit/s
408 kbit/s
824 kbit/s
1032 kbit/s
6 tim eslots
12 tim eslots
16 tim es lots
1240 kbit/s
19 tim es lots
24 kbit/s
56 kbit/s
8 kbit/s
24 kbit/s
792 kbit/s
1592 kbit/s
1992 kbit/s
2392 kbit/s
E1
12 tim eslots
24 tim eslots
Ways ide
24 kbit/s
56 kbit/s
8 kbit/s
304 kbit/s
1624 kbit/s
3256 kbit/s
4072 kbit/s
4888 kbit/s
Gros s
Ways ide
Gros s
E1
Ways ide
Gros s
E1
Ways ide
Gros s
E1
Ways ide
Note C3
Note C4
Note C5
Note C6
40 kbit/s
264 kbit/s
56 kbit/s
E1
Note C2
16 kbit/s
128 kbit/s
8 kbit/s
Ways ide
14 MHz
4 tim es lots
0 kbit/s
Gros s
C6
3 tim es lots
Ways ide
Gros s
C6
2 tim eslots
4 tim eslots
E1
7 MHz
1 tim eslots
1 tim es lots
2 tim eslots
Ways ide
3.5 MHz
80 kbit/s
1 tim es lots
E1
E1
1.75 MHz
112 kbit/s
32 kbit/s
Gros s
1 MHz
96 kbit/s
1 tim eslots
Ways ide
500 kHz
72 kbit/s
8 kbit/s
E1
250 kHz
64 QAM
Ways ide
Ways ide
75 kHz
32 QAM
E1
E1
C4
16 QAM
25 tim eslots
1 E1
31 tim es lots
1 E1
1 E1
2 E1
24 kbit/s
1168 kbit/s
1984 kbit/s
712 kbit/s
2872 kbit/s
5752 kbit/s
7192 kbit/s
8632 kbit/s
1 E1
2 E1
3 E1
4 E1
784 kbit/s
1576 kbit/s
928 kbit/s
280 kbit/s
5720 kbit/s
11448 kbit/s
14312 kbit/s
17176 kbit/s
2 E1
5 E1
6 E1
8 E1
1544 kbit/s
1008 kbit/s
1784 kbit/s
472 kbit/s
11832 kbit/s
23672 kbit/s
29592 kbit/s
35512 kbit/s
5 E1
11 E1
14 E1
17 E1
1392 kbit/s
704 kbit/s
360 kbit/s
16 kbit/s
23992 kbit/s
47992 kbit/s
59992 kbit/s
65464 kbit/s
11 E1
22 E1
28 E1
28 E1
1024 kbit/s
2056 kbit/s
1528 kbit/s
7000 kbit/s
The capacities specif ied are for Unf ramed E1 and so require 2088 kbit/s to transport via the radio.
The management ethernet capacity must be subtracted from the gross capacity (def ault 64 kbit/s).
Available only in the 300 and 400 MHz bands.
Available only in the 300, 400 and 1400 MHz bands.
Available only in the 700, 800 and 900 MHz bands.
Available only in the 2000 and 2500 MHz bands.
Specifications | 239
Capacity FCC D1
Channel size
25 kHz
D2
(20 kHz occ bw)
(part 90)
100 kHz
D3
(part 101)
200 kHz
D4
(part 101)
250 kHz
D5
(part 27)
500 kHz D5
(part 27)
Note D1
Note D2
Note D3
Note D4
Note D5
QPSK
Gros s
T1
32 QAM
64 QAM
56 kbit/s
72 kbit/s
88 kbit/s
0 tim es lots
Ways ide
Gros s
16 QAM
136 kbit/s
1 tim es lots
56 kbit/s
8 kbit/s
24 kbit/s
280 kbit/s
352 kbit/s
424 kbit/s
T1
2 tim es lots
Ways ide
8 kbit/s
24 kbit/s
32 kbit/s
312 kbit/s
632 kbit/s
792 kbit/s
Gros s
T1
Ways ide
Gros s
T1
Ways ide
Gros s
4 tim es lots
4 tim es lots
9 tim es lots
5 tim es lots
56 kbit/s
24 kbit/s
408 kbit/s
824 kbit/s
1032 kbit/s
12 tim es lots
6 tim es lots
40 kbit/s
12 tim es lots
56 kbit/s
6 tim es lots
1 tim es lots
16 tim es lots
1240 kbit/s
19 tim es lots
24 kbit/s
56 kbit/s
8 kbit/s
24 kbit/s
792 kbit/s
1592 kbit/s
1992 kbit/s
2392 kbit/s
1 T1
1 T1
408 kbit/s
808 kbit/s
T1
12 tim es lots
1 T1
Ways ide
24 kbit/s
8 kbit/s
The capacities specif ied are for Unf ramed T1 and so require 1584 kbit/s to transport via the radio.
The management ethernet capacity must be subtracted from the gross capacity (def ault 64 kbit/s).
Available only in the 400 MHz band (available in 1Q2007)
Available only in the 900 MHz band (available in 1Q2007).
Available only in the 900 MHz band
Available only in the 2000 and 2500 MHz bands (available in 1Q2007)
Specifications | 240
Receiver sensitivity R1
Channel size
QPSK
25 kHz
50 kHz
-109 dBm
16 QAM
32 QAM
64 QAM
-105 dBm
-102 dBm
-99 dBm
-103 dBm
-100 dBm
-97 dBm
75 kHz
-107 dBm
-101 dBm
-98 dBm
-95 dBm
100 kHz
-106 dBm
-100 dBm
-97 dBm
-94 dBm
150 kHz
-104 dBm
-98 dBm
-95 dBm
-92 dBm
200 kHz
-102 dBm
-96 dBm
-93 dBm
250 kHz
-101 dBm
-95 dBm
-92 dBm
500 kHz
-99 dBm
-93 dBm
-90 dBm
-87 dBm
1 MHz
-96 dBm
-90 dBm
-87 dBm
-84 dBm
1.75 MHz
-94 dBm
-88 dBm
-85 dBm
-82 dBm
3.5 MHz
-90 dBm
-84 dBm
-81 dBm
-78 dBm
-89 dBm
7 MHz
-87 dBm
-81 dBm
-78 dBm
-75 dBm
14 MHz
-84 dBm
-78 dBm
-75 dBm
-72 dBm
Note R1
Typical perf ormance specified at the antenna port for 10-6 BER.
The receiver is typically 1 dB more sensitive for a BER of 10-3.
System Gain S1,S2
Channel size
QPSK
25 kHz
16 QAM
32 QAM
64 QAM
136 dB
132 dB
128 dB
50 kHz
144 dB
134 dB
130 dB
126 dB
75 kHz
142 dB
132 dB
128 dB
124 dB
100 kHz
141 dB
131 dB
127 dB
123 dB
150 kHz
139 dB
129 dB
125 dB
121 dB
200 kHz
137 dB
127 dB
123 dB
250 kHz
136 dB
126 dB
122 dB
118 dB
500 kHz
134 dB
124 dB
120 dB
116 dB
1 MHz
131 dB
121 dB
117 dB
113 dB
1.75 MHz
129 dB
119 dB
115 dB
111 dB
3.5 MHz
125 dB
115 dB
111 dB
107 dB
7 MHz
122 dB
112 dB
108 dB
104 dB
14 MHz
119 dB
109 dB
105 dB
101 dB
Note S1
Typical perf ormance specified at the antenna port for 10 BER.
-6
The system gain is typically 1 dB greater for a BER of 10-3.
Note S2
Figures reduce by 4 dB for 32 QAM and 8 dB for 64 QAM.
Figures increase by 10 dB for QPSK (9 dB f or the 2000 and 2500 MHz bands).
Specifications | 241
Note: The default Modem Interleaver Mode setting is on for channel sizes of 250 kHz and greater and
off for channel sizes of 200 kHz and less (see “Modem Interleaver Mode” on page 63).
Typical end-to-end link delay (ETSI) - interleaver off L1
Channel size
QPSK
25 kHz
50 kHz
41.8 m s
16 QAM
32 QAM
64 QAM
48.3 m s
38.7 m s
34.2 m s
22.8 m s
19.2 m s
16.4 m s
75 kHz
34.8 m s
18.5 m s
16.2 m s
13.5 m s
100 kHz
26.2 m s
14.6 m s
12.0 m s
10.5 m s
150 kHz
17.4 m s
9.8 m s
8.2 m s
7.4 m s
200 kHz
13.6 m s
7.9 m s
6.9 m s
250 kHz
10.8 m s
6.5 m s
5.5 m s
4.9 m s
500 kHz
5.8 m s
3.9 m s
3.4 m s
3.2 m s
1 MHz
3.67 m s
2.61 m s
2.59 m s
2.55 m s
1.75 MHz
2.93 m s
2.33 m s
2.12 m s
2.03 m s
3.5 MHz
2.40 m s
2.11 m s
2.05 m s
2.08 m s
7 MHz
2.20 m s
1.89 m s
1.77 m s
1.71 m s
14 MHz
2.08 m s
1.83 m s
1.75 m s
1.64 m s
Typical end-to-end link delay (ETSI) - interleaver on L1
Channel size
QPSK
25 kHz
16 QAM
32 QAM
64 QAM
163.0 m s
126.9 m s
110.8 m s
50 kHz
146.7 m s
75.4 m s
62.1 m s
51.5 m s
75 kHz
103.0 m s
52.8 m s
45.5 m s
36.4 m s
100 kHz
78.8 m s
41.1 m s
33.2 m s
28.2 m s
150 kHz
50.9 m s
26.6 m s
21.9 m s
18.9 m s
200 kHz
40.5 m s
21.5 m s
18.0 m s
250 kHz
33.1 m s
17.7 m s
14.5 m s
12.4 m s
500 kHz
17.4 m s
9.5 m s
8.2 m s
7.1 m s
1 MHz
9.31 m s
5.50 m s
4.79 m s
4.44 m s
1.75 MHz
6.04 m s
3.87 m s
3.47 m s
3.16 m s
3.5 MHz
3.79 m s
2.84 m s
2.44 m s
2.54 m s
7 MHz
2.67 m s
2.23 m s
1.92 m s
1.86 m s
14 MHz
2.11 m s
2.01 m s
1.86 m s
1.89 m s
Note L1
The end to end link delays are measured from E1 interface to E1 interface
The delay f igures are typical and can vary w hen the system re-synchronizes
Specifications | 242
Transmitter ETSI
Modulation Type
Frequency bands
Power output range
(in 1 dB steps)
+21 to +35 dBm
QPSK
300, 400, 600, 700, 800, 900 & 1400 MHz bands
QPSK
2000, 2500 MHz bands
+20 to +34 dBm
16 QAM
all bands
+17 to +31 dBm
32 QAM
all bands
+16 to +30 dBm
64 QAM
all bands
+15 to +29 dBm
Transmitter FCC
QPSK
400 MHz band
Power output range
(in 1 dB steps)
+21 to +35 dBm
QPSK
900 MHz band
+15 to +29 dBm
16 QAM
400 MHz band
+17 to +31 dBm
16 QAM
900 MHz band
+15 to +29 dBm
32 QAM
400 MHz band
+16 to +30 dBm
32 QAM
900 MHz band
+15 to +29 dBm
64 QAM
400 MHz band
+15 to +29 dBm
Modulation Type
Frequency bands
Receiver
Maxim um input level
Dynam ic range
B1
C/I ratio
(carrier to interference ratio)
Co-channel
-20 dBm
58 to 87 dB (at 10 -6 BER)
depending on m odulation type and channel s ize
C/I ratio = C dB - IdB
better than 16 dB at QPSK
better than 20 dB at 16 QAM
better than 23 dB at 32 QAM
better than 27 dB at 64 QAM
1s t adjacent channel better than -5 dB
2nd adjacent channel better than -30 dB
Note B1
Typical performance specified at the antenna port for 10-6 BER.
The dynamic range is typically 2 dB greater for a BER of 10-3.
Specifications | 243
Duplexer ETSI F1
Passband
Frequency Bands
TX / RX Split
500 kHz
300, 400 MHz bands
> 5 MHz
2 MHz
300, 400 MHz bands
> 9.45 MHz
3.5 MHz
300, 400 MHz bands
> 20 MHz
7 MHz
700 MHz band
> 30 MHz
14 MHz
600 MHz band
> 45 MHz
800, 900 MHz bands
> 40 MHz
1400 MHz band
> 48 MHz
2000 MHz band
> 91 MHz
2500 MHz band
> 74 MHz
Duplexer FCC / IC F1
Passband
Frequency Bands
TX / RX Split
500 kHz
400 MHz band
> 3 MHz
1 MHz
900 MHz band
> 9 MHz
Note F1
Bandpass duplexer
Contact 4RF for other duplexer options
Specifications | 244
Interface specifications
Ethernet interface
General
Diagnostics
Interface
RJ-45 * 4 (Integrated 4-port switch)
Cabling
CAT-5 UTP, supports auto MDIX (Standard Ethernet)
Maximum line length
100 metres on cat-5 or better
Bandwidth allocation
n x 8 kbit/s up to max available.
n x 64 kbit/s is recommended for higher bandwidth terminals
500 kHz, 32 QAM.
Maximum is 16384 kbit/s (or limited by radio bandwidth).
Maximum packet size
‘Standard’ Ethernet packets: max 1518 octets
Tagged and double-tagged packets: max 1526 octets
Data buffer size
Up to 256 frames
Address table size
2048 IP addresses
WAN protocol
HDLC
Ethernet mode
10Base-T or 100Base-TX
Full duplex or half duplex
(Auto-negotiating and auto-sensing)
VLAN tagging
IEEE 802.1Q VLAN tagging
QoS
IEEE 802.1p
Ipv4 TOS DiffServ
Ipv6 traffic class
Spanning Tree
Forwards 802.1D Spanning Tree Protocol packets up to 1526
bytes in length.
Hardware
Green LED (solid): Link OK
Green LED (flashing): Data traffic
QJET Quad E1 / T1 interface
General
Diagnostics
Standard
G.703 and G.704
Interface
RJ-45
Line termination impedance
E1 120 Ω balanced
T1 100 Ω balanced
Maximum line length
E1 typically up to 1.7 km (43 dB of loss at 1024 kHz in
standard 0.4 mm2 cable).
T1 typically up to 1.7 km (36 dB of loss at 772 kHz in standard
0.4 mm2 cable).
Bandwidth allocation
Framed E1s require a link bandwidth of 2048 kbit/s.
Unframed E1s require a link bandwidth of 2088 kbit/s.
Framed T1s require a link bandwidth of 1544 kbit/s.
Unframed T1s require a link bandwidth of 1584 kbit/s.
Line code
E1 HDB3 or AMI
T1 B8ZS or AMI
Tx Waveform Shaper
(T1 only)
0 ~ 133 ft
133 ~ 266 ft
266 ~ 399 ft
399 ~ 533 ft
533 ~ 655 ft
Stability
±50 ppm
Jitter performance
G.823 (sections 2 & 3)
Hardware
Green LED: Link OK
Yellow LED: Loss of signal
Specifications | 245
Q4EM Quad 4 wire E&M interface
General
Analogue
Signalling
Diagnostics
Audio
64 kbit/s (PCM A-Law as per ITU G.711)
32, 24 & 16 kbit/s (ADPCM as per ITU G.726 and ANSI
TI.303)
E&M signalling
8 kbit/s per port
Maximum line length
400 metres
Transmission performance
characteristics
ITU G.712 E4 for an operating level range of -14 dBr to +4
dBr
Input level range
-14.0 dBr to +4.0 dBr in 0.5 dB steps
Output level range
-14.0 dBr to +4.0 dBr in 0.5 dB steps
Default output level
0 dBr
Default input level
0 dBr
Maximum level
+3.14 dBm0
Port impedance
600 Ω
Return loss
better than 25 dB over the frequency range 200 - 3600 Hz
Transformer isolation
3.88 kV
End to end gain
Frequency response
0 dB ± 0.1 dB (300-3000 Hz)
0 dB ± 0.5 dB (250-3400 Hz)
Audio line protection
Secondary protection
Signal to total distortion
> 30 dB (0 dBm0 to -30 dBm0)
> 22 dB (-45 dBm0)
E&M
Mode independent (external power supply / ground reference
required)
Pulse distortion
4:1 multiplexed < 2.250 ms
Non-multiplexed ≤ 250 µs
M loop current
5.0 to 6.5 mA (constant current)
M detection voltage
9 VDC
M maximum voltage
60 VDC
E circuit impedance
45 Ω closed
> 100 kΩ open
Maximum E circuit current
100 mA
E maximum voltage
60 V
E&M circuit protection
E: Current limited to 120 mA, overvoltage to 350 V
M: Current limited to 6.5 mA, overvoltage to 100 V
Hardware
Green LED: M circuit active
Yellow LED: E circuit active
Specifications | 246
DFXO Dual foreign exchange office interface
General
Analogue
Audio
64 kbit/s (PCM as per ITU G.711)
32, 24 and 16 kbit/s (ADPCM as per ITU G.726 and ANSI
TI.303)
Signalling allocation
8 or 32 kbit/s allocated for CAS
Companding
A-Law or µ-Law
Maximum line length
600 metres (2000 feet) on 0.4 mm / 26 AWG copper pair
Calling line ID (CLI)
Support provided for ETSI: EN 300 659-1 & 2 and BT: SIN
227 and 242
Fax
Conforms to G3 standard for 64 kbit/s PCM and 32 kbit/s
ADPCM compression
Transmission performance
characteristics
ITU G.712 E2 for an operating level range of -6 dBr to +1 dBr
Input level range
-10 dBr to +1.0 dBr in 0.5 dB steps
Output level range
-10 dBr to +1.0 dBr in 0.5 dB steps
Default Input level
-4.0 dBr
Default Output level
-1.0 dBr
Maximum level
+3.14 dBm0
Line impedance / Hybrid
balance impedance options
600 Ω
900 Ω
600 Ω + 2.16 µF
900 Ω + 2.16 µF
270 Ω + 750 Ω || 150 nF (TBR-21)
220 Ω + 820 Ω || 120 nF (TN12)
370 Ω + 620 Ω || 310 nF (BT3)
320 Ω + 1050 Ω || 210 nF (BT Network)
200 Ω + 680 Ω || 100 nF (China)
Return Loss
better than 20 dB over the frequency range 200 - 3600 Hz
Trans hybrid loss
better than 30 dB between 300 - 3400 Hz (with matched
external line and hybrid balance impedance)
Common mode rejection ratio
better than 40 dB over the frequency range 50 - 3600 Hz
Echo Canceller
provides up to 64 ms of echo cancellation
Specifications | 247
Signalling
Pulse dialing
Transparent decadic signalling at 7 - 14 PPS with break
period limits of 60 - 73 %
Pulse distortion
4:1 multiplexed < 2.250 ms
Non-multiplexed ≤ 250 µs
Reversals
Line polarity reversal detection
Metering level sensitivity
12 kHz / 16 kHz billing tone detection with a selectable level
sensitivity of -17dBm to -40 dBm in 1dB steps into 200 Ω
(60 mV rms to 5 mV rms into 200 Ω).
Metering level maximum
The maximum level of metering signal the DFXO can tolerate
without voice band interference is 0.8 Vrms into 200 Ω.
Loop resistance on-hook
>1 MΩ
Ringing detection threshold
Options of 16 Vrms, 26 Vrms or 49 Vrms
Ringing detection frequency
15 to 50 Hz sine wave
Ringing input impedance
Option of >10 MΩ or 30kΩ
Ringing DC offset range
tolerance
0 to -75VDC
Ringing input voltage
maximum
up to 100 Vrms
Physical
Physical interface
Dual RJ-45 per port (1 line port, 1 monitor port)
Diagnostics
Green LED
On: Normal operation
Solid: Off-hook
Flashing: Ringing
Yellow LED
On: Alarm
Flashing: Loopback
Specifications | 248
DFXS Dual foreign exchange subscriber interface
General
Analogue
Audio
64 kbit/s (PCM as per ITU G.711)
32, 24 and 16 kbit/s (ADPCM as per ITU G.726 and ANSI
TI.303)
Signalling Allocation
8-32 kbit/s allocated for CAS
Compression coding
A-Law or µ-Law
Maximum line length
600 metres (2000 feet) on 0.4 mm / 26 AWG copper pair
Calling line ID (CLI)
Support provided for ETSI: EN 300 659-1 & 2 and BT: SIN
227 and 242
Fax
Conforms to G3 standard for 64 kbit/s PCM and 32 kbit/s
ADPCM compression
Transmission performance
characteristics
ITU G.712 E2 for an operating level range of -6 dBr to +2.5
dBr
Input level range
-9.0 dBr to +3.0 dBr in 0.5 dB steps
Output level range
-9.5 dBr to +2.5 dBr in 0.5 dB steps
Default Input level
+1.0 dBr
Default Output level
-6.0 dBr
Maximum level
+3.14 dBm0
Line impedance / Hybrid
balance impedance options
600 Ω
900 Ω
600 Ω + 2.16 µF
900 Ω + 2.16 µF
220 Ω + (820 Ω || 120 nF) (TN12)
270 Ω + (750 Ω || 150 nF) (TBR21)
370 Ω + (620 Ω || 310 nF) (BT3)
Return Loss
better than 20 dB over the frequency range 200 - 3600 Hz
Trans hybrid loss
better than 30 dB between 300 - 3400 Hz (with matched
external line and hybrid balance impedance)
Common mode rejection ratio
better than 40 dB over the frequency range 50 - 3600 Hz
Specifications | 249
Signalling
Physical
Diagnostics
Feed voltage output
-48 V (160 + 160 Ω voltage source current limited)
Loop current limit
35 mA
Seize signal
Loop start only (no ground start)
Loop detect threshold
10 - 12 mA (step function between on hook and off hook)
Non loop current
4 - 6 mA (step function between on hook and off hook)
Pulse dialing
Transparent decadic signalling at 7 - 14 PPS with break
period limits of 60 - 73 % (with loop current > 23 mA)
Pulse distortion
4:1 multiplexed < 2.250 ms
Non-multiplexed ≤ 250 µs
Reversals output
Line polarity reversal output (optional)
Metering output voltage
12 kHz / 16 kHz billing tone generation with four selectable
output voltages of 100 mV, 200 mV, 300 mV and 400 mV rms
into 200 Ω sourced via the Line Impedance setting but limited
to a maximum open circuit voltage of 1 Vrms.
Ringer waveform
Sinusoidal with a maximum total distortion of 10% (into 3 REN
load)
Ringer voltage (open circuit)
Five selectable ringer output voltages sourced via an internal
ringing resistance of 178 Ω per port.
The ringing output is a composite balanced AC ringing voltage
with a differential DC offset voltage.
60 Vrms + 0 VDC
55 Vrms + 10 VDC
50 Vrms + 18 VDC
45 Vrms + 22 VDC
40 Vrms + 24 VDC
Ringer frequency output
Options of 17, 25 or 50 Hz ±5%
Ringer power output
60 Vrms source into a load of 2 REN
45 Vrms source into a load of 3 REN
(1 REN ≈ 6930 Ω in series with 8 μF)
Ring Trip
Ring Trip will ocurr in < 150 ms following DC loop of > 15 mA
Ring Trip Immunity
Ring Trip will not ocurr if the DFXS outputs ringing into a load
of 500 Ω in series with 4.4μF or less.
Physical interface
Dual RJ-45 per port (1 line port, 1 monitor port)
Line protection
Secondary protection (4RF recommends the use of external
primary protection in lightning prone areas)
Green Led
Green LED
On: Normal operation
Solid: Off-hook
Flashing: Ringing
Yellow LED
On: Alarm
Flashing: Loopback
Specifications | 250
QV24 Quad V.24 asynchronous data interface
General
Interface
ITU-T V.24/EIA/TIA RS-232E
Bandwidth allocation
8-120 kbit/s in 8 kbit/s steps (dependent on rate selected)
Control line allocation
8 kbit/s
Maximum line length
10 metres
Data clamp
Mark hold when out of sync.
Control line clamp
Off when loss of sync.
Clock
Internally generated from 2.048 MHz system clock
(synchronized at both ends)
Transparent mode
Operation is completely transparent but limited to 0-600 bit/s
Standard mode data bits
7,8
Standard mode parity
Transparent (enable / disable)
Standard mode stop bits
1,2
Data rates (bit/s)
300, 600, 1200, 2400, 4800, 7200, 9600, 12800, 14400,
19200, 23040, 28800, 38400, 57600 and 115200
Control
signals
End-to-end
CTS-RTS, DSR-DTR
Diagnostics
Green LED
RD data traffic
Yellow LED
TD data traffic
Async
parameters
HSS Single high speed synchronous data interface
General
Diagnostics
Interfaces
ITU-T V.24 EIA/TIA RS-232E
ITU-T V.35
ITU-T V.36 EIA/TIA RS-449
ITU-T X.21
EIA/TIA 530
Bandwidth allocation
8-2048 kbit/s in 8 kbit/s steps (dependent on rate selected)
8 kbit/s for control lines
Maximum line length
3 metres
Clock
Internally generated from 2.048 MHz system clock
(synchronized at both ends) on DCE to DCE mode.
Clock provided by external DCE when in DTE mode.
Remote DCE outputs clock-timed by incoming clock at DTE.
Top Green LED
On: Normal operation
Flashing: Loopback
Lower Green LED
On: Normal operation
Specifications | 251
External alarm interfaces
Alarm inputs
Alarm outputs
Overall
Detector type
Isolated current detectors
Detection current
5.0 to 6.5 mA (constant current)
Detection voltage
9 to 60 VDC or AC rms
Contact type
Isolated semiconductor relay type contacts
Maximum current
100 mA
Maximum voltage
0 to 60 VDC or AC rms
Ouput impedance
45 Ω closed
> 100 kΩ open
Latency
The latency for an alarm presented on an external alarm input
to the alarm being output on an external alarm output is < 2
seconds
Auxiliary interfaces
Management
Configuration and
management
Embedded web server and / or SNMP accessed via Ethernet
interface or across link
Test points
RSSI
Front panel test point for measuring the RSSI voltage
Specifications | 252
Power specifications
AC Power supply
Nominal
voltage
Input voltage
range
Power consumption
Max VA
Frequency
115 VAC
103 - 127 Vrms
63 - 180 W
400 VA
47 - 63 Hz
230 VAC
207 - 254 Vrms
63 - 180 W
400 VA
47 - 63 Hz
DC Power supply
Nominal
voltage
Input voltage
range
Power consumption
Maximum input current
±12 VDC
10.5 to 18 VDC
63 - 180 W
18 A
±24 VDC
20.5 to 30 VDC
63 - 180 W
8A
±48 VDC
40 to 60 VDC
63 - 180 W
4A
Power consumption
Power Consumption (min – max)
63 - 180 W Input power (dependent on interface cards fitted and
modulation type / output power level)
Terminal only:
QPSK + 19 dBm
65 W
QPSK + 29 dBm
68 W
QPSK + 32 dBm
72 W
QPSK + 35 dBm
75 W
64 QAM + 15 dBm
63 W
64 QAM + 29 dBm
71 W
Interface cards:
QJET four port E1 card
1.9 W (all states)
Q4EM four port 4W E&M card
0.75 W (all states)
QV24 four port V.24 card
0.75 - 1 W (all states)
DFXO two port 2W FXO card
0.75 W (all states)
DFXS two port 2W FXS card
One DFXS card installed with both ports idle (on hook): 3.8 W
Plus:
1.3 W / line off-hook (200 ohm copper loop plus 450 ohm
telephone)
2.6 W / line ringing (60 Vrms 25Hz source via 50 ohm copper loop
into a 1 REN load)
4.1 W / line ringing (45 Vrms 25Hz source via 50 ohm copper loop
into a 3 REN load)
HSS single port high speed data
1 W (all states)
MHSB:
Tributary and RF switch
16 W not switched
28 W switched
Specifications | 253
MHSB specifications
MHSB protection
RF switch
Tributary switch
TX relay loss
≈ 1.5 dB
Splitter loss
≈ 3.5 dB
Switching time
< 25 ms seconds from detection of alarm condition
RF path restore time
< 10 seconds
Ports
General specifications
Environmental
Operating range
-10 to +50˚ C
Storage range
-20 to +70˚ C
Humidity
Maximum 95% non-condensing
Altitude
Up to 5000 metres
Mechanical
19-inch rack mount
2 U high (internal duplexer)
3 U high (external duplexer)
Width
434 mm (without mounting brackets attached)
483 mm (with mounting brackets attached)
Height
88 mm
Depth
372 mm
Colour
Pure black
Weight
≈ 8 kg (per terminal)
ETSI performance
Radio
EN 301 751, EN 300 630
EN 302 217 Parts 1, 2.1, and 2.2
EMI/EMC
EN 301 489 Parts 1 & 4
Safety
EN 60950
Environmental
ETS 300 019 Class 3.2
Product end of life | 255
19. Product end of life
End-of-life recycling programme (WEEE)
The WEEE Directive concerns the recovery, reuse, and recycling of electronic and electrical
equipment. Under the Directive, used equipment must be marked, collected separately, and disposed
of properly.
4RF Communications has implemented an end-of-life recycling programme to manage the reuse,
recycling, and recovery of waste in an environmentally safe manner using processes that comply with
the WEEE Directive (EU Waste Electrical and Electronic Equipment 2002/96/EC).
The WEEE symbol explained
This symbol appears on Electrical and Electronic Equipment (EEE) as part of the WEEE (Waste EEE)
directive. It means that the EEE may contain hazardous substances and must not be thrown away with
municipal or other waste.
WEEE must be collected separately
You must not dispose of electrical and electronic waste with municipal and other waste. You must
separate it from other waste and recycling so that it can be easily collected by the proper regional
WEEE collection system in your area.
Return and collection programmes in your area
Contact your local or regional authority for information about the return and collection programmes
available in your area.
Your role in the recovery of WEEE
By separately collecting and properly disposing of WEEE, you are helping to reduce the amount of
WEEE that enters the waste stream.
One of the aims of the WEEE directive is to divert EEE away from landfill and encourage recycling.
Recycling EEE means that valuable resources such as metals and other materials (which require
energy to source and manufacture) are not wasted. Also, the pollution associated with accessing new
materials and manufacturing new products is reduced.
EEE waste impacts the environment and health
Electrical and electronic equipment (EEE) contains hazardous substances which have potential effects
on the environment and human health. If you want environmental information on the Aprisa XE
terminal, contact us (on page 15).
Abbreviations | 257
20. Abbreviations
ADC
Analogue to Digital Converter
MAC
Media Access Control
ADPCM
Adaptive Differential Pulse Code
Modulation
Mbit/s
Megabits per second
MHSB
Monitored Hot Standby
ADSL
Asymmetrical Digital Subscriber Line
MHz
Megahertz
AGC
Automatic Gain Control
MIB
Management Information Base
AMP
Amplifier
MTBF
Mean Time Between Failures
BER
Bit Error Rate
MTTR
Mean Time To Repair
CAS
Channel Associated Signalling
ms
milliseconds
CPE
Customer Premises Equipment
NFAS
Not Frame Alignment Signal (E1
frame)
CLI
Calling Line Identification
DAC
Digital to Analogue Converter
NMS
Network Management System
dB
Decibels
OSI
Open Systems Interconnection
dBc
Decibels relative to carrier power
PABX
Private Automatic Branch Exchange
dBm
Decibels relative to 1 mW
PBX
Private Branch Exchange
dBr
Decibels relative to the tramsmission
reference point
PC
Personal Computer
PCM
Pulse Code Modulation
DCE
Data Communications Equipment
PCA
Printed Circuit Assembly
DS0
Digital Signal 0 - 64 kbit/s Timeslot
PLL
Phase Locked Loop
DTE
Data Terminal Equipment
POP
Point of Presence
DTI
Digital Trunk Interface
POTS
Plain Old Telephone Service
E&M
Ear and Mouth
ppm
Parts Per Million
EMC
Electro-Magnetic Compatibility
PSTN
Public Switched Telephone Network
EMI
Electro-Magnetic Interference
PMR
Public Mobile Radio
ESD
Electro-Static Discharge
QAM
Quadrature Amplitude Modulation
ETSI
European Telecommunications Standards
Institute
QPSK
Quadrature Phase Shift Keying
FAS
Frame Alignment Signal (E1 frame)
RAI
Remote Alarm Indicator
RF
Radio Frequency
FEC
Forward Error Correction
RoHS
Restriction of Hazardous Substances
FFE
Feed Forward Equalizer
RSSI
Received Signal Strength Indication
F/W
Firmware
RX
Receiver
FXO
Foreign Exchange Office
SNMP
Simple Network Management Protocol
FXS
Foreign Exchange Subscriber
SNR
Signal to Noise Ratio
GSM
Global System for Mobile communications
SWR
Standing Wave Ratio
HSC
Hardware Software Compatibility
TCP/IP
HSS
High-Speed Synchronous Serial
Transmission Control Protocol/Internet
Protocol
H/W
Hardware
TCXO
IC
Integrated Circuit
Temperature Compensated Crystal
Oscillator
IF
Intermediate Frequency
TETRA
Terrestrial Trunk Radio
IP
Internet Protocol
TFTP
Trivial File Transfer Protocol
I/O
Input/Output
TMR
Trunk Mobile Radio
ISP
Internet Service Provider
TX
Transmitter
kbit/s
Kilobits per second
UTP
Unshielded Twisted Pair
kHz
Kilohertz
VCO
Voltage Controlled Oscillator
LAN
Local Area Network
VDC
Volts DC
LED
Light Emitting Diode
VoIP
Voice over Internet Protocol
LOS
Loss of Signal
WEEE
mA
Milliamps
Waste Electrical and Electronic
Equipment
Acknowledgments and licensing | 259
21. Acknowledgments and licensing
The Aprisa XE product software runs the GNU Linux Operating System and incorporates several other
packages in accordance with the free software philosophy.
The following list identifies the licensed software used:
BusyBox
Description: Tiny versions of common UNIX utilities
Reference: http://busybox.net/
License Type: GNU General Public License (GPL)
DropBear SSH Server
Description: Small and secure SSH Server
Reference: http://matt.ucc.asn.au/dropbear/
License Type: MIT Style License
GoAhead WebServer 2.1
Description: Embedded Web Server
Reference: http://webserver.goahead.com/
License Type: Private License
Linux Kernel
Description: Linux Kernel version 2.4.26
Reference: http://www.kernel.org/
License Type: GNU General Public License (GPL)
Net-SNMP
Description: Various tools relating to SNMP
Reference: http://www.net-snmp.org/
License Type: CMU/UCD and BSD License
uClibc
Description: C library for embedded Linux systems
Reference: http://uclibc.org/
License Type: GNU Lesser General Public License (LGPL)
U-Boot
Description: Bootloader
Reference: http://u-boot.sourceforge.net/
License Type: GNU General Public License (GPL)
Acknowledgments and licensing | 260
Software licensed under the GPL
Some of the above packages licensed under the GPL have been modified by 4RF Communications
Limited. The copyright holders of these modified packages (including 4RF Communications Limited)
agree to them being distributed under the terms of the General Public License.
Copies of the GNU General Public License (GPL) and Lesser General Public License (LGPL) can be
obtained from the Free Software Foundation Inc, 59 Temple Place - Suite 330, Boston, MA, 021111307, USA. Plain text copies of these licenses can also be found at:
http://www.gnu.org/licenses/gpl.txt
http://www.gnu.org/licenses/lgpl.txt
If you would like a copy of the GPL source code used in this product on a CD, please send US$50.00
(to cover the preparation of the CD and transport costs) to 4RF Communications Limited, PO Box 13506, Wellington, New Zealand.
Software licensed under other licences
The following copyright notices are included for packages not covered by the GPL:
Dropbear SSH Server (MIT License)
Dropbear—a SSH2 server
Copyright © 2002, 2003 Matt Johnston
All rights reserved
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and
associated documentation files (the "Software"), to deal in the Software without restriction, including
without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to
the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial
portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
Acknowledgments and licensing | 261
Net-SNMP
Part 1: CMU/UCD (BSD like)
Copyright © 2001-2003, Networks Associates Technology, Inc
All rights reserved.
Redistribution and use in source and binary forms, with or without modification, are permitted provided
that the following conditions are met:
Redistributions of source code must retain the above copyright notice, this list of conditions and the
following disclaimer.
Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the
following disclaimer in the documentation and/or other materials provided with the distribution.
Neither the name of the Networks Associates Technology, Inc nor the names of its contributors may
be used to endorse or promote products derived from this software without specific prior written
permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS''
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
Part 2: Networks Associates Technology, Inc. (BSD)
Copyright © 2001-2003, Networks Associates Technology, Inc
All rights reserved.
Redistribution and use in source and binary forms, with or without modification, are permitted provided
that the following conditions are met:
Redistributions of source code must retain the above copyright notice, this list of conditions and the
following disclaimer.
Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the
following disclaimer in the documentation and/or other materials provided with the distribution.
Neither the name of the Networks Associates Technology, Inc nor the names of its contributors may
be used to endorse or promote products derived from this software without specific prior written
permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS''
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
Acknowledgments and licensing | 262
Part 3: Cambridge Broadband Ltd (BSD)
Portions of this code are copyright © 2001-2003, Cambridge Broadband Ltd.
All rights reserved.
Redistribution and use in source and binary forms, with or without modification, are permitted provided
that the following conditions are met:
Redistributions of source code must retain the above copyright notice, this list of conditions and the
following disclaimer.
Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the
following disclaimer in the documentation and/or other materials provided with the distribution.
The name of Cambridge Broadband Ltd. may not be used to endorse or promote products derived
from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDER "AS IS'' AND ANY EXPRESS OR
IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE FOR ANY DIRECT, INDIRECT,
INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
Part 4: Sun Microsystems, Inc. (BSD)
Copyright © 2003 Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
California 95054, U.S.A. All rights reserved.
Use is subject to license terms below.
This distribution may include materials developed by third parties.
Sun, Sun Microsystems, the Sun logo and Solaris are trademarks or registered trademarks of Sun
Microsystems, Inc. in the U.S. and other countries.
Redistribution and use in source and binary forms, with or without modification, are permitted provided
that the following conditions are met:
Redistributions of source code must retain the above copyright notice, this list of conditions and the
following disclaimer.
Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the
following disclaimer in the documentation and/or other materials provided with the distribution.
Neither the name of the Sun Microsystems, Inc. nor the names of its contributors may be used to
endorse or promote products derived from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS''
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
Acknowledgments and licensing | 263
Part 5: Sparta, Inc. (BSD)
Copyright © 2003-2004, Sparta, Inc
All rights reserved.
Redistribution and use in source and binary forms, with or without modification, are permitted provided
that the following conditions are met:
Redistributions of source code must retain the above copyright notice, this list of conditions and the
following disclaimer.
Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the
following disclaimer in the documentation and/or other materials provided with the distribution.
Neither the name of the Networks Associates Technology, Inc nor the names of its contributors may
be used to endorse or promote products derived from this software without specific prior written
permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS''
AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE
LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
POSSIBILITY OF SUCH DAMAGE.
GoAhead WebServer (Private License)
GoAhead WebServer
Copyright (c) 2000 GoAhead Software, Inc. All Rights Reserved
Commissioning Forms | 265
22. Commissioning Forms
Commissioning Forms | 266
Index | 267
23. Index
2 wire .............................................................. 91
4 wire .............................................................. 89
AC power supply ............................................ 35
access rights................................................... 57
accessory kit................................................... 17
AIS................................................................ 206
alarms
alarm summary........................................ 199
clearing alarms ........................................ 203
E1 / T1 alarm conditions ......................... 206
external...................................................... 31
history...................................................... 201
identifying causes.................................... 204
interface alarms....................................... 202
termination................................................. 31
types........................................................ 229
A-law............................................................... 94
altitude ............................................................ 23
antennas
aligning .................................................... 165
checking polarization............................... 165
corner reflector .......................................... 21
directional antennas ............................ 19, 20
installing .................................................... 30
parabolic.................................................... 19
selection and siting.................................... 19
siting .......................................................... 21
yagi ............................................................ 20
attenuators...................................................... 37
balun transformer ......................................... 212
basic terminal settings.................................... 64
bench setup .................................................... 37
BER .............................................................. 171
browser cache, clearing ............................... 180
cabling
accessory kit.............................................. 17
coaxial feeder ...................................... 22, 37
for protected terminals ............................ 157
shielded ................................................... 218
cache, clearing ..................................... 179, 180
CAS ........................................ 94, 136, 137, 138
Castle Rock.................................................... 67
CD contents ................................................... 16
clock source
setting for .......................................... 87, 109
compatibility of interfaces............................. 133
configuration files ......................................... 182
configuration, saving .............................. 66, 130
constellation analyser................................... 173
corner reflector antenna ................................. 21
country specific settings ............................... 235
cross connections
creating ................................................... 127
deleting.................................................... 132
drop and insert ........................................ 129
point to point ........................................... 127
printing .................................................... 131
saving configurations .............................. 130
selecting timeslots................................... 139
sending configurations ............................ 130
Symmetrical Connection Wizard............. 148
cross connections application
about ....................................................... 123
ethernet capacity..................................... 125
getting configurations.............................. 126
installing .................................................. 122
toolbar ..................................................... 124
total assigned link capacity ..................... 123
user capacity........................................... 125
Cross Connections application
required system configuration for ........... 121
DC power supply............................................ 32
DCD mode ................................................... 113
declaration of conformity .................................. iii
DFXO interface card .................................... 101
country specific settings.......................... 235
cross connections for .............................. 144
interface connections for......................... 218
port settings for ....................................... 101
signalling for............................................ 144
DFXS interface card....................................... 94
country specific settings.......................... 235
cross connections for .............................. 144
interface connections for......................... 217
port settings for ......................................... 94
signalling for............................................ 144
directional antennas ................................. 19, 20
Drop & Insert capacity.................................. 124
DSR DTR mode ........................................... 112
E&M interface................................................. 89
E1
Index | 268
alarm conditions ...................................... 206
framed ............................................. 135, 136
unframed ................................................. 135
earthing............................................... 22, 24, 37
EIA-530......................................................... 109
environmental requirements........................... 23
error counters ............................................... 171
Ethernet
capacity ................................................... 125
port status.................................................. 86
Quality of Service ...................................... 82
VLAN tagging ............................................ 80
exchange end ............................................... 101
external alarms
configuring................................................. 74
inputs......................................................... 74
mapping..................................................... 76
outputs....................................................... 76
fade margin................................................... 170
fault finding ................................... 169, 197, 207
feeder cables .................................................. 22
framed mode ................................................ 135
framed modes
PCM30C mode........................................ 136
PCM31C mode........................................ 136
T1 ESF 16 mode ..................................... 138
T1 ESF 4mode ........................................ 138
T1 ESF mode .......................................... 137
T1 SF 4 mode.......................................... 137
T1 SF mode............................................. 137
frequency bands..................................... 25, 237
front panel
connections ............................................... 27
indicators ................................................... 27
RF protection switch................................ 155
tributary switch ........................................ 154
gateway
factory default............................................ 56
handshaking
DCD mode............................................... 113
DSR DTR mode ...................................... 112
RTS CTS mode ....................................... 111
hardware
accessory kit.............................................. 17
installing .............................................. 29, 30
hot stand-by.................................................. 153
HSS clocking
clocking types ......................................... 115
cloud mode ............................................. 119
internal clocking ...................................... 115
pass-through clocking ............................. 115
pipe mode ............................................... 116
primary/secondary master clocking ........ 115
synchronous clock selection modes ....... 114
HSS interface card ....................................... 109
cross connections for .............................. 146
handshaking............................................ 111
interface connections for......................... 219
port settings for ....................................... 109
humidity.......................................................... 23
image files .................................................... 184
updating table of ..................................... 188
in-service commissioning ............................. 163
installation ................................................ 29, 31
interface cabling ............................................. 32
interface cards
before installing....................................... 192
configuring................................................. 79
installing .................................................. 194
port settings .............................................. 79
summary ................................................... 77
types.......................................................... 28
interface connections ................................... 211
DFXO ...................................................... 218
DFXS....................................................... 217
Ethernet................................................... 213
HSS......................................................... 219
Q4EM ...................................................... 214
QJET ....................................................... 212
QV24 ....................................................... 228
interface pinouts
HSS......................................................... 219
interface traffic direction ............................... 211
interfaces, compatibility................................ 133
IP address
factory defaults.......................................... 56
for protected terminals ............................ 158
network...................................................... 48
terminal ..................................................... 65
understanding ........................................... 47
Java
clearing cache......................................... 179
requirement for............................ 16, 43, 121
LEDs
Index | 269
identifying colours.................................... 204
interface...........212, 213, 214, 217, 218, 219
RF protection switch................................ 156
tributary protection switch ....................... 155
lightning protection ......................................... 24
link budget ...................................................... 22
link capacity, assigned ................................. 124
link performance ................................... 169, 173
LOF............................................................... 206
logging in
SuperVisor................................................. 54
Loop interface circuits .................................... 91
loopbacks
about ....................................................... 197
interface lookbacks.................................. 198
timeslot loopbacks................................... 198
LOS .............................................................. 206
maintenance ................................................. 175
major alarms, mapping................................... 76
management
ethernet capacity ..................................... 125
MHSB ........................................................... 153
MIB
saving ........................................................ 66
minor alarms, mapping................................... 76
modify user group........................................... 57
Monitored Hot Stand-by (MHSB).................. 153
mounting kit .................................................... 17
operating temperature .................................... 23
passwords
changing.................................................... 59
path planning .................................................. 19
path propagation calculator ............................ 19
PCM modes.......................... 135, 136, 137, 138
performance, of link...................... 169, 173, 174
pinouts .......................................................... 218
DFXS....................................................... 217
Ethernet................................................... 213
Q4EM ...................................................... 214
QJET ....................................................... 212
QV24 ....................................................... 228
Synchronous cable assemblies............... 220
POTS................................................ 91, 94, 101
power
AC power................................................... 35
DC cabling................................................. 33
DC power .................................................. 32
power supply ............................................ 23, 32
powering up .................................................. 164
protected terminals....................................... 153
cabling..................................................... 157
clearing alarms for .................................. 161
configuring radios for .............................. 158
IP addressing .......................................... 158
mounting ................................................. 159
power supply........................................... 157
Q4EM interface card
cross connections for .............................. 143
E&M signalling types............................... 215
interface connections for......................... 214
port settings for ......................................... 89
QJET interface card
cross connections for .............................. 134
interface connections for......................... 212
modes ............................. 135, 136, 137, 138
port settings for ......................................... 87
Quality of Service (QoS) ................................ 82
QV24 interface card ..................................... 108
baud rate ................................................. 145
cross connections for .............................. 145
interface connections for......................... 228
port settings for ....................................... 108
rack space...................................................... 29
RAI ............................................................... 206
rebooting the terminal .................................. 189
receiver .......................................................... 26
RF protection switch
front panel ............................................... 155
LEDs ....................................................... 156
RF settings ..................................................... 61
modem performance................................. 63
RS-232 synchronous data ........................... 109
RS-449 synchronous data ........................... 109
RS-530 ......................................................... 109
RSSI
alarm threshold ......................................... 73
aligning the antennas.............................. 167
RTS CTS mode............................................ 111
safety earth .................................................... 36
setup menu
COM port settings ..................................... 40
Hyperterminal............................................ 40
setup basic settings .................................. 51
signalling mode ............................................ 144
slave tributary switch.................................... 156
slots
Index | 270
configuring............................................... 196
terminal...................................................... 28
SNMP ............................................................. 67
MIB details................................................. 70
setting access controls.............................. 68
setting trap destinations ............................ 69
viewing traps ............................................. 70
specifications ................................................ 237
auxiliary interfaces................................... 251
DFXO interface........................................ 246
DFXS interface ........................................ 248
environmental.......................................... 253
ethernet interface .................................... 244
ETSI ........................................................ 253
external alarms interface......................... 251
frequency bands...................................... 237
general .................................................... 253
HSS interface .......................................... 250
mechanical .............................................. 253
MHSB ...................................................... 253
power....................................................... 252
Q4EM interface ....................................... 245
QJET interface ........................................ 244
QV24 interface ........................................ 250
system performance................................ 238
standby mode ............................................... 155
static damage, avoiding................................ 194
storage temperature ....................................... 23
subnet mask
factory default............................................ 56
subscriber end ................................................ 94
SuperVisor...................................................... 53
logging into ................................................ 54
logging out................................................. 54
opening page............................................. 55
PC requirements for .................................. 43
PC settings for........................................... 44
Surveyor ......................................................... 19
syslog ........................................................... 207
error logging ............................................ 207
remote logging......................................... 209
T1
alarm conditions ...................................... 206
framed ..................................... 135, 137, 138
unframed ................................................. 135
temperature .................................................... 23
terminal
alarm summary ....................................... 199
applying power........................................ 164
clocking ..................................................... 71
earthing ......................................... 24, 36, 37
installing .................................................... 29
logging into................................................ 54
logging out................................................. 54
modules..................................................... 26
near and far, explained ............................. 47
operating conditions.................................. 23
power supplies .......................................... 32
rebooting ................................................. 189
synchronizing .......................................... 169
upgrading ........................................ 177, 182
terminal emulator ........................................... 66
test equipment.............................................. 172
TFTP server ................................................. 177
timed reboot ................................................. 189
timeslots
PCM modes ............................................ 136
selecting .................................................. 139
tools................................................................ 29
traffic direction of interfaces ......................... 211
tranformer, Balun ......................................... 212
transmitter ...................................................... 26
tributary switch
front panel ............................................... 154
LEDs ....................................................... 155
slaves ...................................................... 156
troubleshooting............................................. 197
unframed mode ............................................ 135
upgrading the terminal
uploading system files............................. 182
using TFTP server .................................. 177
user ethernet capacity.................................. 125
users
access rights ............................................. 57
adding ....................................................... 57
changing passwords ................................. 59
deleting...................................................... 58
disabling .................................................... 58
reset to defaults ........................................ 66
saving user information............................. 58
session details .......................................... 59
user groups ............................................... 57
view user group......................................... 57
V.24
asynchronous data.................................. 108
synchronous data.................................... 109
V.35 / V.36 ................................................... 109
Index | 271
web browser cache, clearing........................ 180
WEEE ........................................................... 255

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Modify Date                     : 2006:11:30 12:46:43+13:00
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Mod Date                        : 2006:11:30 12:46:43+13:00
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4RF N0400025A0200A POINT TO POINT DIGITAL RADIO SYSTEM (RECEIVER) User Manual USERS MANUAL 3

4RF Limited POINT TO POINT DIGITAL RADIO SYSTEM (RECEIVER) USERS MANUAL 3

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USERS MANUAL 3

FCC ID Filing: UIPN0400025A0200A

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