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When installed, the SNIB, SNIB2, or SNIB3 expansion board enables a DIGI*TRAC or Mx controller to be programmed, monitored, and controlled from a properly-configured IBM-compatible host PC running the Velocity software. Communication is secured by Hirsch’s proprietary Hirsch Encrypted Standard (HES) protocol SCRAMBLENET network.

SNIB

The SNIB provides both RS-232 and RS-485 SCRAMBLE*NET ports. If you need to connect the host to the master SNIB via RS-485, you can only use the SNIB; otherwise, you have a choice of either SNIB or SNIB2. An example of the SNIB is shown in Figure 1-1.

When installed, the SNIB, SNIB2, or SNIB3 expansion board enables a DIGI*TRAC or Mx controller to be programmed, monitored, and controlled from a properly-configured IBM-compatible host PC running the Velocity software. Communication is secured by Hirsch’s proprietary Hirsch Encrypted Standard (HES) protocol SCRAMBLENET network.

• An optically isolated RS-232 port is provided on the original SNIB and the SNIB2.

• An optically isolated RS-485 port (required for multi-drop or long hardwired connections) is provided on the SNIB, the SNIB2, and the SNIB3.

• An RJ-45 Ethernet port (which requires a host-to-master controller TCP/IP connection) is provided on the SNIB2 and the SNIB3.

The following subsections provide installation instructions for the “SNIB”, the “SNIB2” , and the “SNIB3”.

SNIB Board

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Figure 1-1: SNIB Board

An example of the possible SNIB connections is shown in Figure 2-23.

SNIB Connections

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Figure 2-2: SNIB Connections

SNIB Cabling Distance

The power and data lines are fully isolated from the controller, providing immunity from transients and common-mode ground voltages between the SNIB-connected controller(s) and a host PC. Maximum SNIB cabling lengths are shown in Table 1-1:

Table 1-1: SNIB Cabling Distances

For a single controller network, connect to the S*NET via either an RS-485 or RS-232 port. If connecting more than one controller on the network and the first controller is within 50 feet (15 meters) of the Host PC, connect the PC to the first controller via the RS- 232 connector and the rest of the controllers to the RS-485 S*NET connector on the first controller.

Alternatively, simply connect to the RS-485 connector and daisy-chain the wire to the multiple controllers. The M1N does not require a SNIB to network because SNIB circuitry with both RS-232 and RS-485 connectors is embedded on the controller board.

SNIB Design

When installed in a DIGI*TRAC Controller, the SNIB enables the Controller to be programmed, monitored, and controlled from a PC. For a one-controller network, you can connect to either the SNIB’s RS-485 connector (up to 4000 feet/1220 meters) or the RS-232 connector (up to 50 feet/15 meters).

If you are connecting to more than one controller on the network and the first controller is within 50 feet (15 meters) of the Host PC, you can connect the PC to the first controller via the RS-232 connector and the rest of the controllers to the RS-485 S*NET connector on the first controller. Alternatively, simply connect to the RS-485 connector and daisy-chain the wire to the multiple controllers.

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Figure 1-3: The Original Secure Network Interface Board (SNIB)

Figure 1-4 provides examples of how the SNIB can be used to connect two controllers to a host PC using either an RS-232 or RS-485 connection.

Figure 2-65: Host PC to SNIB Wiring Examples

Installing The SNIB

This section includes installation instructions for the original SNIB.

SNIB Setup

The wiring and settings of the SNIB are shown in Figure 1-5.

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Figure 1-5: Secure Network Interface Board (SNIB)

MD1 - 2

Because the M1N has integrated SNIB circuitry, the DIP switches are located on the controller itself, to either side of the network connections. (Refer to Figure 2-1 on page 2-4.)

Model 1N Design

The M1N has one heavy-duty door relay with associated line module input for supervision and door functions. This relay is capable of powering two keypads. The M1N also has three additional inputs for door contacts and alarm sensoring and four control relays to monitor and activate various relay circuits. Relay 4 can double as an alarm relay but it is not dedicated to that task.

In addition, the M1N includes an integrated SNIB for direct connection via either RS-232 or RS-485 to a SCRAMBLE*NET network, a keypad connector, and a printer port.

The M1N is shown in the below Figure:

Set these switches as you would a normal SNIB. There are no SNIB jumpers on the M1N.

The board has two jumpers, MD1 and MD2. Both are explained here:

There are also a number of DIP switches on the SNIB which can configure the board.

SW1/SW2

The last controller on any network cable run, or any single controller connected to a modem through the RS-232 port, must have its terminating resistors set to ON. To do this, set both SW1 and SW2 on switch bank S1 to ON.

SW3/SW4

The switch bank at S2 has 9 switches which configure a number of properties for the SNIB. SW3 determines the Modem Mode.

SW5/SW6

SW5-6 determines the SNIB’s baud rate. The rates you can select depend on the SNIB version you have.

Older (pre-1998) SNIBs have a ‘16450’ or ‘16C450’ serial port. Look for ‘16450’ or ‘16C450’ on the big rectangular chip. This works with 2400 and 9600 bps and may work with 19200 bps as well (depending on the SNIB date). DIP switch settings for this are:

Current production SNIBs have a ‘16550’ or ‘16C550’ serial port processor. Look for ‘16550’ or ‘16C550’ on the big rectangular chip. This configuration should work on all three baud rates.

DIGI*TRAC 7.0 supports 19,200 bps SCRAMBLENET. This means that while 9600 and 2400 are supported by both the 1200 and 300 baud rates are supported by the older SNIB.

To do this, set the SNIB DIP switch 5 (the third one on the second set of dip switches) to ON, and set the Test Tool or equivalent host software (or Xbox) to 19200 bps

If you’re using an Xbox with your controllers, the SNIB baud rate on all controllers must match the XBox’s ‘Net Speed’ baud rate. Current production XBoxes only allow 2400 or 9600 bps baud rates. When changing baud rates, you must stop and restart all controllers on the network as well as all XBoxes.

SW7 - SW12

SW7-12 are used to set the Network Address. Each switch represents a binary value in this way:

The only exception to this scheme is Network Address 64 where SW7-12 are all OFF. (This is currently not supported by SAM.) Table 1-2 provides a complete list of all network addresses and their corresponding switch setup:

Table 1-2: SNIB DIP Switch Network Address Settings

a. Velocity software does not recognize Address 64.

SNIB Mounting

The SNIB should always be the top board installed on the standoffs. Install all other boards first (underneath the SNIB), then the SNIB.

To install the SNIB expansion board:

1. Turn all system power off, remove connectors to the standby battery, then remove connectors to the AC power.

2. Install the board on the supplied standoffs and connect the EBIC5 cable as described in “Connecting Expansion Boards”.

SNIB Wiring

To connect SCRAMBLE*NET to this board:

1.Turn all system power off, remove connectors to the standby battery, then remove connectors to the AC power.

2. Connect the wires on one end of the cable to the terminal block you require – either the RS-232 or S*NET (RS-485) port. Both RS-232 and RS-485 use SCRAMBLE*NET protocol. If necessary, you can remove the terminal blocks and replace them after you’ve wired them.

The wires are connected in this way:

For RS-485 S*NET Cabling:

3.Connect the other end of the cable to the RS-485 of a NET*ADAPT, NET*MUX4, or to the serial port of the PC (with NAPC installed).

SNIB Pinout Information

The following tables provide pinout information on connections between the SNIB and a number of devices and connectors.

SNIB Testing

After installing the board and connecting to a PC, you can test the SNIB using Host PC software.

SNIB2

SNIB2 Board

SNIB2 Connections

SNIB2 Design

Benefits of SNIB2

Installing the SNIB2

SNIB2 Network Configuration Options Overview

Deploying SNIB2

Configuring a Master SNIB2 on the Same Subnet

Configuring a Master SNIB2 in a Different Subnet

Resetting SNIB2 Encryption Keys

Resetting the SNIB2 to its Factory Default Values

Controller and SNIB2 LED Diagnostics

Special Light Patterns: Start Up
Normal Operation

SNIB3

SNIB3 Design

SNIB3 Board

Benefits of SNIB3

Prerequisites for SNIB3

Installing and Configuring the SNIB3

Providing Surge Protection for a Master SNIB3

Preparing an Mx-Controller to Use a SNIB3

Installing the SNIB3 in a Controller without a SNIB or a SNIB2

Replacing a Controller's SNIB or SNIB2 by a SNIB3

SNIB3 Network Configuration Options

Using Ethernet

Using Serial RS-485

RS-485 Cabling for SNIB3s

Using NET*MUX4s with SNIB3s

Setting the DIP Switches on a SNIB3

Configuring a SNIB3

Overview of Network Subnets 

Using Velocity to Configure a SNIB3 on the Same Subnet

Configuring a SNIB3 on a Different Subnet

Resetting SNIB3 Encryption Keys

Resetting a SNIB3 to its Factory Default Values

Controller and SNIB3 LED Diagnostics

Special Light Patterns at Startup

Light Patterns for Normal Operation