Amanda Work Group Installation Manual

							Chapter 3: Installing RDSP/RTNI Boards 19
11. Run Setup to obtain tone patterns
12. Run Setup to define telephone switching system integration patterns
13. Run Setup to define Amanda system configuration options
Requirements
Before installing the RDSP/x000 board, verify that the host system meets 
each of the following requirements:
 Bus speed is 8 MHz with 0 wait states or 10 MHz with 1 wait state
 Can provide +5v 3.0 A power to the RDSP/x000 board
These requirements are in addition to those for the system.
Configuring an RDSP/x000 Voice Board
The following figure shows the locations of the jumper blocks and 
connectors on the RDSP/x000 board. The tables below it describe those 
jumper blocks and connectors and show how to jumper the RDSP/x000 
board for use with Amanda.
Later sections of this chapter offer more detailed explanations about how to 
jumper this board. 
						

							20 Installing [email protected]/DOS
The RDSP/x000 Board
Jumper Block and Connector Information
Closed means that two pins are covered/connected by the shorting jumper, 
and Open means that the two pins are not covered/connected by the shorting 
Table 1: Jumper Positions for Use with Amanda
LabelTypeDescription12345678
W1Jumper 
block DSi MVIP 
streamOpenOpenOpenOpenOpenOpenClosedOpen
W2Jumper 
block DSo MVIP 
streamOpenOpenOpenOpenOpenOpenClosedOpen
W3Jumper 
block Base I/O 
portClosedClosedClosedClosedClosedOpenOpen
W4Jumper 
block MVIP ter-
minationClosedClosed
J2ConnectorMVIP bus
J2
W1
W2
W3
2
140
39
W4 
						

							Chapter 3: Installing RDSP/RTNI Boards 21
jumper. In the diagrams in this chapter, the blacked out pin positions 
represent closed positions.
T
IP:Installers often place shorting jumpers over only one pin 
when the position is Open. This does not connect the pins, 
but it does prevent losing jumpers.
Understanding MVIP Streams
MVIP is a standard protocol for connecting PC resources. The MVIP bus 
provides both physical and logical half-duplex internal connections for up to 
512 resources.
The MVIP bus is segmented into 8 bidirectional serial data streams, each 
composed of a pair of unidirectional streams. Each unidirectional stream can 
carry 2.048 megabits of data per second, partitioned by Time Division 
Multiplexing into 32 64-kilobits-per-second (Kb/sec.) time slots. A single 
MVIP time slot has sufficient bandwidth to do either of the following:
 Carry PCM voice data
 Be a 64 Kb/sec. pipe for data communications
Numbering schemes for both streams and time slots start with 0. An MVIP 
board is configured to use one of the eight streams on the bus. The port 
associated with each time slot is made up of two half-duplex connections. 
W1
W2
W4
W3 
						

							22 Installing [email protected]/DOS
During configuration, each resource on the board is mapped to a discrete 
time slot of the stream.
For example, the stream on an RDSP/24000 board automatically maps time 
slots 1, 9, 17, and 25 to RDSP resources to 1, 2, 3, and 4, respectively. The 
port associated with Time Slot 4 has two halves: the input designated DSi4, 
and the output DSo4. The network interface board is the point of reference 
for input and output.
Configuring MVIP Streams
Each RDSP/x000 board uses two MVIP streams: one for receiving and one 
for transmitting. The RDSP/x000 board can receive on one of the DSi 
streams (DSi0 through DSi7) and can transmit on one of the DSo streams 
(DSo0 through DSo7). Each RDSP/x000 board is factory-configured to use 
streams DSi6 and DSo6. The Amanda Company recommends that you keep 
these settings.
The DSi stream jumper block consists of a pin position for each DSi stream. 
If you look at the board with the bracket on your right, the leftmost pin 
position corresponds to DSi0, the next pin position corresponds to DSi1, and 
so on. The rightmost pin position corresponds to DSi7. 
The DSo stream jumper block has the same construction as the DSi stream 
jumper block with the leftmost pin position corresponding to DSo0 and the 
rightmost pin position corresponding to DSo7.
To configure the DSi and DSo streams:
1. Find the jumper block for the DSi and DSo streams on the board.
The jumper block for the DSi MVIP stream is labeled W1. It is below 
the MVIP connector if the bracket is to your right.
The jumper block for the DSo MVIP stream is labeled W2. It is below 
the MVIP connector and the W1 block if the bracket is to your right. 
						

							Chapter 3: Installing RDSP/RTNI Boards 23
2. The settings should be as shown below:
3. Only the second to last pin position should be closed with a shorting 
jumper. 
C
AUTION:Do not add or remove shorting jumpers while power is 
applied to the board.
Configuring the MVIP Termination
Each RDSP/x000 can terminate the C2 MVIP and C4 MVIP bus signals. In a 
series of boards that are on an MVIP bus, the boards at both ends must 
terminate C2 and C4 while the other boards must not terminate the signals. 
For example, the following figure shows three boards on an MVIP bus. The 
left and right boards must terminate the MVIP bus signals while the middle 
board must not. Each RDSP/x000 is configured at the factory to terminate 
both C2 and C4.
W1
W2 
						

							24 Installing [email protected]/DOS
The MVIP termination block consists of two pin positions, one for the C2 
and one for the C4. If you look at the board with the bracket on your right, 
the pin position on the left corresponds to C4 and the pin position on the right 
corresponds to C2. The Amanda Company assumes that you are installing 
only one RDSP/x000 board and, therefore, that it should terminate both 
signals.
To terminate both MVIP bus signals:
1. Find the MVIP termination block on the board.
It is labeled W4 and is below the MVIP connector at the right of the W1 
block if the bracket is to your right.
2. For use with Amanda, close both signals’ pin positions using shorting 
jumpers (as shown below).
C
AUTION:Do not add or remove shorting jumpers while power is 
applied to the board.
W4 
						

							Chapter 3: Installing RDSP/RTNI Boards 25
Configuring the Base I/O Port
Each RDSP/x000 uses 47 I/O ports in addition to its base I/O port. Seven of 
these additional I/O ports are contiguous to the base I/O port. For example, if 
the RDSP/x000’s base I/O port is 300H, then the seven contiguous I/O ports 
are 301H, 302H, 303H, 304H, 305H, 306H and 307H. The RDSP/x000 also 
uses five additional I/O ports offset from the base I/O port and each of its 
seven contiguous I/O ports:
 I/O port plus 400H
 I/O port plus 800H
 I/O port plus C00H
 I/O port plus 1000H
 I/O port plus FC00H
Each RDSP/x000 board is factory-configured to use base I/O port 300H. If 
you are installing more than one RDSP/x000 board, you need to change the 
base I/O ports so that each board has a unique base I/O port. If you are 
installing only one RDSP/x000 board, you need to change its base I/O port 
only if there is an I/O port conflict with another device.
Each RDSP/x000 must use a base I/O port in the range 0000H through 
3FFH. The Amanda Company assumes that you are installing only one 
RDSP board and recommends that you use base I/O port 300H.
To configure the base I/O port:
1. Find the jumper block for the base I/O port. 
It is labeled W3 and is below the W2 block if the bracket is to your 
right.
2. Set W3 for use with Amanda as shown below. 
Close the five positions on the left using shorting jumpers and open the 
two positions on the right.
W3 
						

							26 Installing [email protected]/DOS
CAUTION:Do not add or remove shorting jumpers while power is 
applied to the board.
Configuring an RTNI-xATI Voice Board
An RTNI-xATI board’s main function is connecting any line resource with 
any other line or MVIP resource. This is commonly called switching. Your 
RTNI-xATI board provides Analog-to-MVIP switching. The line resource 
for your ATI board is analog, but only digital PCM signals can be switched, 
so the board must convert the incoming analog signal to PCM prior to 
switching. This conversion is made by the board’s loop start module which 
links the MVIP bus and a trunk line. Amanda uses only the linking function 
and not the switching function of MVIP.
The following figure shows the locations of the jumper blocks and 
connectors on the RTNI-xATI board. The tables below it describe those 
jumper blocks and connectors. They also show how to jumper the RTNI-
xATI board for use with Amanda.
HexJumper positions
RowAddress0123456
1300ClosedClosedClosedClosedClosedOpenOpen 
						

							Chapter 3: Installing RDSP/RTNI Boards 27
Closed means that two pins are covered/connected by the shorting jumper, 
and Open means that the two pins are not covered/connected by the shorting 
jumper. 
LabelTypeDescription
Jumper 
Settings
JumpersEJ10Jumper blockBase I/O AddressOpen
Open
Closed
Closed
Closed
Closed
Open
Closed
Closed
Closed
W1Jumper blockMVIP TerminationClosed
W2Jumper blockMVIP TerminationClosed
ConnectorsJ1ConnectorMVIP bus
J4ConnectorTelephony Cable
EJ10W1
W2 
						

							28 Installing [email protected]/DOS
Configuring the MVIP Termination
The MVIP termination block consists of two pin positions, one for the C2 
and one for the C4. The top pin position (labeled W1) corresponds to C4 and 
the next pin position (labeled W2) corresponds to C2. 
You should close both pin positions. The Amanda Company assumes that 
you are installing only one RTNI-xATI board along with an RDSP/x000 
board. In this case, this board should terminate both signals.
To terminate both MVIP bus signals:
1. Find the MVIP termination block on the board.
One pin position is labeled W1 and the other is labeled W2. They are 
located just below the J1 connector with the bracket on your right.
2. For use with Amanda, close both signals’ pin positions using shorting 
jumpers (as shown below).
C
AUTION:Do not add or remove shorting jumpers while power is 
applied to the board.
Configuring the Base I/O Port
Each voice board must have a unique base I/O port. Each RTNI-xATI board 
is factory-configured to use base I/O port 308H. It uses the base I/O port and 
three others, calculated as offsets of the base I/O port. These I/O ports are:
 Base I/O port
 Base I/O port plus 400H
 Base I/O port plus 800H
 Base I/O port plus C00H
W1
 
W2