NGP Hardware Installation Guide

PERPETUAL INNOVATION

NGP Hardware Installation Guide

Lenel NGP Hardware Installation Guide, product version 6.4 This guide is item number 55-6000E, revision 1.018, December 2010

Copyright © 2010 Lenel Systems International, Inc.All rights reserved. Information in this document is subject to change without notice. No part of this document may be reproduced or transmitted in any form or by any means, electronic or mechanical, for any purpose, without the express written permission of Lenel Systems International, Inc.

Portions of this software (Linux Kernel 2.6.25, Pthreads, and Buildroot) are licensed under the GNU General Public License, version 2, June 1991, which is copyright 1989, 1991 Free Software Foundation, Inc.

A portion of this software (YAFFS2) is licensed under the GNU General Public License, version 3, 29 June 2007, which is copyright 2007 Free Software Foundation, Inc.

Portions of this software (uClibc, iClibc locale, GPG Gnu Privacy Guard, gpgme GnuPG Made Easy) are licensed under the GNU Lesser General Public License, version 3, 29 June 2007, which is copyright 2007 Free Software Foundation, Inc.

A portion of this software (OpenSSL) is licensed under the Modified BSD License, which is copyright 1999-2009 The OpenSSL Project.

Portions of this software [CMockery, Google Protocol Buffers (C)] are licensed under the Apache License, Version 2.0 (the “License”); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an “AS IS” BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License.

A portion of this software [Google Protocol Buffers (C++)] is licensed under the New BSD License. THIS PORTION OF THE 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 HOLDER 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.

A portion of this software (mini_httpd) is licensed under the Acme Labs Freeware License. Copyright © 2000 by Jef Poskanzer <[email protected]>. All rights reserved.

Redistribution and use in source and binary forms of this portion, with or without modification, are permitted provided that the following conditions are met:

1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.

2. 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.

THIS PORTION OF THE SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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.

Non-English versions of Lenel documents are offered as a service to our global audiences. We have attempted to provide an accurate translation of the text, but the official text is the English text, and any differences in the translation are not binding and have no legal effect.

The software described in this document is furnished under a license agreement and may only be used in accordance with the terms of that agreement. Lenel is a registered trademarks of Lenel Systems International, Inc.

Microsoft, Windows, Windows Server, and Microsoft Windows Vista are either registered trademarks or trademarks of Microsoft Corporation in the United States and/or other countries. Other product names mentioned in this User Guide may be trademarks or registered trademarks of their respective companies and are hereby acknowledged.

The software included in this product contains copyrighted software that is licensed under the GPL. You may obtain the complete Corresponding Source code from us for a period of three years after our last shipment of this product, which will be no earlier than 20132-02-2708-30, by sending a money order or check for $5 to the following address: Lenel Systems International, Inc., 1212 Pittsford-Victor Road, Pittsford, NY 14534-3820. Please write “source for NGP” in the memo line of your payment. You may also find a copy of the source at http://www.lenel.com. This offer is valid to anyone in receipt of this information.


Table of Contents

Installation Guidelines ..........................................................7

1. Inputs, Outputs and Interface Signals .................................................... 91.1 Power Inputs ......................................................................................................... 9

1.2 Inputs .................................................................................................................... 9

1.3 Reader Inputs and Outputs ................................................................................ 10

1.4 Relay Outputs ..................................................................................................... 10

1.5 RS-485 Communications .................................................................................... 10

2. System Wiring and Other Considerations ............................................ 142.1 General Wiring Considerations ........................................................................... 14

2.2 Ground Wiring .................................................................................................... 15

2.3 Input Wiring ........................................................................................................ 16

2.4 RS-485 Communication Wiring .......................................................................... 17

2.5 Relay Contact Protection .................................................................................... 17

3. System Startup Considerations ........................................................... 193.1 Device Configuration Checks ............................................................................. 19

3.2 Ground Potential Difference Checks Before Connecting .................................... 19

4. Maintenance ........................................................................................ 214.1 Firmware Updates .............................................................................................. 21

5. UL Certified Installations ...................................................................... 225.1 Power ................................................................................................................. 23

5.2 Typical Combinations for UL Installations ........................................................... 24

Enclosure ...........................................................................27

6. NGP Enclosure .................................................................................... 296.1 Anti-attack Bushing Cap ..................................................................................... 30

6.2 Mounting an Enclosure ....................................................................................... 30

Next Generation Panel .......................................................33

7. Overview of the NGP ........................................................................... 357.1 Interfaces ............................................................................................................ 35

7.2 The NGP Board .................................................................................................. 36

revision 1 — 3

Table of Contents

8. Installation ............................................................................................ 388.1 Wiring ................................................................................................................. 38

8.2 Memory Backup Battery ..................................................................................... 46

8.3 Installing Jumpers ............................................................................................... 46

8.4 Web Configuration .............................................................................................. 47

9. Status ................................................................................................... 499.1 NGP Board LEDs ............................................................................................... 49

9.2 SOM Board LEDs ............................................................................................... 49

9.3 Replace Battery .................................................................................................. 51

10. Specifications ..................................................................................... 52

Peripheral Devices .............................................................55

11. 16 Input Control Module NGP-1100 .................................................. 5711.1 Packing List ...................................................................................................... 57

11.2 Mounting the Module ........................................................................................ 58

11.3 VBUS ................................................................................................................ 59

11.4 Input Wiring ...................................................................................................... 59

11.5 Power ............................................................................................................... 59

11.6 Status LEDs ...................................................................................................... 59

11.7 Final Steps ........................................................................................................ 60

11.8 Specifications ................................................................................................... 60

12. 8 Output Relay Control Module NGP-1208 ....................................... 6112.1 Packing List ...................................................................................................... 61


12.3 Output Relay Expansion Module ...................................................................... 62

12.4 Jumpers ............................................................................................................ 62

12.5 Status LEDs ...................................................................................................... 63

12.6 Final Steps ........................................................................................................ 63

12.7 Specifications ................................................................................................... 63

13. Dual Door Interface Module NGP-1320 ............................................. 6413.1 Packing List ...................................................................................................... 65


13.3 Wiring ............................................................................................................... 67

13.4 Jumpers ............................................................................................................ 69

13.5 Status LEDs ...................................................................................................... 69

13.6 Door Contact Detail and Request to Exit .......................................................... 70

13.7 Final Steps ........................................................................................................ 70

13.8 Specifications ................................................................................................... 70

14. NGP Intelligent Power Supply 120-3650/120-3651 ........................... 7214.1 Packing List ...................................................................................................... 73

4 — revision 1



14.3 Jumpers ............................................................................................................ 76

14.4 Status LEDs ...................................................................................................... 77

14.5 Power Supply LCD Keypad Diagnostics ........................................................... 77

14.6 Main Panel and Power Supply AC Condition Calibration ................................. 78

14.7 Voltage and Current Conditions ....................................................................... 78

14.8 Power Supply Displays ..................................................................................... 78

14.9 Specifications ................................................................................................... 78

15. Worldwide Modem 120-3633L ........................................................... 8015.1 Worldwide Modem with 8 output STU .............................................................. 80

15.2 Packing List ...................................................................................................... 81


15.4 Status LEDs ...................................................................................................... 81

15.5 CPU Failure ...................................................................................................... 82

15.6 Enable Line Failure ........................................................................................... 82

15.7 Specifications ................................................................................................... 82

Index .................................................................................................................. 85

revision 1 — 5

Table of Contents

6 — revision 1

INSTALLATION GUIDELINES


1 Inputs, Outputs and Interface Signals

Hardware products operate from various power sources and communicate via a variety of I/O interfaces. Understanding the power requirements and interface signals, their characteristics, merits and limitations will insure successful installation and a reliable system.

1.1 Power Inputs

1.1.1 AC Power

The AC power wiring to power supplies consists of the AC LINE, AC NEUTRAL, and SAFETY GROUND. These lines from the AC power source to the power input terminals must not be interchanged.

Interchange of the AC LINE and AC NEUTRAL exposes components within the power supply to the hot side of the input power even if the AC line switch is turned off. This presents a safety hazard.

Interchange of the AC LINE and SAFETY GROUND places the supply chassis to an AC potential equal to the input voltage. This could result in a lethal shock hazard or equipment damage.

The interchange of the AC NEUTRAL and SAFETY GROUND may result in ground current flowing through the power supply chassis and other ground paths, causing unreliable/improper system operation.

A continuously-on primary power source is required, therefore, the AC LINE input in the hardware power supplies is appropriately fused and switched. Local safety regulations may require an additional switch/fuse to be installed in the NEUTRAL input.

The power applied from the mains to the transformer in the enclosure is 120 VAC for North America (230 VAC for Europe, 240 VAC for Australia; neither of these have been evaluated by UL). The AC power to the panel at connector CN2 is 18 VAC.

1.1.2 DC Power

All Lenel hardware products can use a DC power source.

When using a DC power supply for a hardware product, the DC power must be isolated electrically from the AC input side and regulated DC power.

To insure reliable operation of all components of the system, it is important that all power supplies used to power the devices are completely isolated from the AC power source.

1.2 Inputs

1.2.1 Supervised Alarms

For contact supervision, the inputs require an end-of-line (EOL, 1K10%) terminator to be installed with the contact to be monitored. This can be configured within the access control software. Input protection is similar to that of the unsupervised input, however the input is also filtered to reject 50/60 Hz AC coupling.

revision 1 — 9

Installation Guidelines

The supervised input can sense contact conditions of INACTIVE, ACTIVE, and FAULT. In Alarm Monitoring, the status of the point will be shown as fault. It also accommodates normally closed (NC) and normally open (NO) contacts, which is configurable within the application.

1.3 Reader Inputs and Outputs

1.3.1 Reader Data Input

Reader data input is similar to unsupervised alarm input. Reader data input interfaces to reader DATA 1/DATA 0 (WD1/WD0, or Clock/Data for magnetic reader interfaces) open collector signals and produces a nominal signal swing of 0 to 5 volts.

1.3.2 Open Collector Output

Open collector output is used by readers to control external LEDs. Pull-up resistors and diode clamps are provided for reader data outputs.

1.4 Relay Outputs

The relay outputs are dry contacts that are capable of switching signals for connections to Class 2 power circuits only. However, once they are used to switch current (for example, a door strike), they cannot be used reliably to switch small signals (for example, dialer input). Refer to each panel’s installation instructions of relay output circuits.

1.5 RS-485 Communications

The EIA RS-485 standard defines an electrical interface for multi-point communication on bus transmission lines. It allows high-speed data transfer over extended distance (4000 feet/1219 m.) The RS-485 interface uses a balanced differential transceiver to reject common mode noise. The following table is a comparison of interfaces commonly used in access or alarm systems.

Unlike the RS-232C or current loop interfaces, the RS-485 interface allows multiple devices to communicate at high data rates on a single cable, over long distance. Obviously, the RS-485 interface

RS-485 RS-232C Modem 20 mA Loop

Mode of Operation:

Differential DC coupled

Single-ended DC coupled

Differential AC coupled

Single-ended current

DC Isolation:

No No Yes Usually Isolated

Distance: 4000 feet 50 feet Phone Line 1000 feet

No. of Devices on 1 Line:

32 2 2 Limited by Loop Voltages

Data Rate: 10M bps 20K bps 19.2K bps 2400 bps

10 — revision 1


provides advantages in cost savings for installation and improved system performance, but it also brings about problems which would not commonly be seen on systems using RS-232C or current loop interfaces.

Using long communication cable with multiple devices often necessitates powering devices from different power sources. This can result in ground faults and ground loops, which can cause communication problems and possible equipment damage. Because the RS-485 interface communicates in the base band and provides no DC isolation, ground fault places devices at different electrical ground levels and causes large ground currents to flow. Possibilities of ground fault call for careful system planning and installation verification.

Communication cables exceeding 4000 feet (1219 m) can also create noise and signal reflection problems if proper cable is not used or if the cable is not correctly terminated.

Belden Wire Specifications

Trade NumberUL NEC TypeCSA Certification

Number of Pairs

Nominal D.C. R.Conductor

Shield Nominal Impedance (Ohms)

Nominal Capacitance

pF/feet pF/meter

9841

NEC CM CSA

1 24.0 ohms/M

78.7 ohms/km

3.35 ohms/M

11.0 ohms/K

120 12.8 42

9842

NEC CM CSA

2 24.0 ohms/M

78.7 ohms/km

2.2 ohms/M

7.2 ohms/K

120 12.8 42

88102

NEC CMP CSA

2 24.0 ohms/M

78.7 ohms/km

15.5 ohms/M

50.9 ohms/km

100 12.95 42

Cable Cross Reference Table

Purpose Cable type

Gauge Cond. Descrip-tion

Belden number

South West number

WCW part number

WP number

RS-485, 2-wire

Non-plenum

22 2P overall shield

9841 170050 42007 n/a

RS-485, 2-wire

Plenum 22 2P overall shield

82841, 89841

110050 42002 n/a

RS-485, 4-wire

Non-plenum

22 2P overall shield

9842 170105 C4842 n/a

RS-485, 4-wire

Plenum 22 2P overall shield

88102 110060 42003 n/a

revision 1 — 11


1.5.1 RS-485 Cable

The NGP uses 2-wire RS-485 half-duplex communication. The main run RS-485 cable used must be shielded, low capacitance, two twisted pairs with 100-ohm characteristic impedance or better (Belden 9842 4-wire or 9841, 2-wire, plenum cabling Belden 88102, West Penn, or equivalent). Wire size is 22 AWG minimum. Total length of the communication cable must not exceed 4000 feet (1219 m) for 22 AWG wire size per leg of the communication tree.

Drops (down leads or stubs) to readers and other devices must be kept as short as possible (no longer than 10 feet). Use shielded 22 AWG cable (Belden 9502, or equivalent), when terminating 2-wire RS-485 Weco screw terminal plugs.

Connect the cable shield (drain wire) to the earth ground lug on the panel (only terminated at one end).

1.5.2 Device to Device Connection

Communication cables for RS-485 should be laid out in a daisy chain. Long stubs (T connection) should be avoided because they create discontinuities and degrade signals.

1.5.3 Cable Termination

RS-485 communications is designed for higher data transmission speeds and also simplifies installation by allowing each device to be multi-dropped from a single communication line or bus. With the increased data speeds and transmitting and receiving the data over a single communications line, there is higher risk of external noise. External noise could be in the form of line impedance, line ringing, or RF interference. When using the specified communications cabling the risk of noise is all but eliminated. To ensure that the data is sent and received without error, some End-of-Line termination of the RS-485 bus may be required.

• RS-485 Cable termination from host to controller The device used to convert RS-232 communication to RS-485 determines the termination necessary for this segment of the RS-485 communication bus. These communications devices, pre-bias the RS-485 signal, which marks the state

RS-232 Non-plenum

22 5 overall shield

9610 170155 C0953 n/a

Plenum 22 6 overall shield

83506 110070P C3165 n/a

Reader drops

Non-plenum

22 6 overall shield

5504FE, 9536

161240 C0743 3270


6504FE 110253P 444351-04 253270B

12 VDC power

Non-plenum

18 2 overall shield

5300FE, 8760

163004 414109 293


6300FE, 88760

112000P 442320 25293B

Cable Cross Reference Table

Purpose Cable type

Gauge Cond. Descrip-tion

Belden number

South West number

WCW part number

WP number

12 — revision 1


of the signal being sent and allows the line to flow for reliable communications. This is true for most devices that are used for Host to ISC communications, but any device that has been approved by Lenel will indicate how termination should be configured for proper operation in its documentation. Refer to the specific device diagrams being used in the following sections of this hardware manual.

• RS-485 Cable termination from controller to down stream modules (NGP-1100, 1320, CKxx) Termination of this section of the RS-485 bus always remains the same. Each end of the RS-485 bus must be terminated using the on-board jumpers provided with each piece of OnGuard hardware. Please refer to the termination drawings for each component being installed in this hardware manual.

• RS-485 Cable termination from controller to third-party hardware devices Termination may be different for each RS-485 hardware device that is connected to the controller. Please refer to the model being used for the hardware installation application.

revision 1 — 13


2 System Wiring and Other Considerations

Proper installation is essential to the safe and reliable operation of the OnGuard system. Improper or incorrect wiring will lead to unreliable operation or damage to system components. When system components are powered by different power sources, great care must be exercised in planning and wiring the system. The following paragraphs provide some guidelines for successful system interconnection.

2.1 General Wiring Considerations

There are different system wiring considerations for different groups of wiring, depending on the signal levels the wires are to carry. System wires can be generally separated into the following groups:

• Power distribution wires (non-power limited)

• Data communication wires (Class 2 power limited)

• Sensor wires (Class 2 power limited)

To avoid cross-talk, follow the wire requirements for each type of communication, or use different conduit for different signal groups.

2.1.1 Device Placement

Observe the distance limitation of each type of signal when planning device placement. Modems and line extenders can be used for extended distance.

Do not route any wires near utility AC power wiring, lightning rod grounding wire, lighting ballasts, inductive loads such as motors, etc. to avoid externally generated transients. Grounding is required for EMC protection and safety.

2.1.2 Power Requirements

When planning a system, know the power requirement of each device. If multiple devices are to share a common power supply, care must be exercised to avoid excessive voltage loss on the wires. Voltage loss can lead to communication problems when devices are talking/listening on different grounds.

Voltage loss is directly proportional to wire resistance and the current the wire carries. Place the power supply as close to the equipment as possible. Select appropriate wire size for the load.

2.1.3 Current Overload

When designing any system, you must know the power requirement of each component being used within that system (refer to 8.1.6 Power) as well as the actual output of the power supplies being used. If multiple devices are to share a common power supply, care must be taken to avoid excessive voltage loss through the power transmitting wires. Voltage loss can lead to intermittent communications problems when devices are consuming more power than the power supply is able to provide. Other causes of voltage loss are directly proportional to wire resistance and current that the wire carries. When designing a system, place the power supply as close to the equipment as possible. The farther away the equipment is from the power supply, the larger the gauge of wire needed to ensure adequate current is being supplied at the device. Be sure to select the appropriate wire size for the distance between the power source and the equipment.

14 — revision 1


When choosing a power supply, never exceed the maximum output current. Always use a 25% overage factor when sizing your supply as a safety operation. Always use an isolated, regulated power supply.

For a complete listing of our products, consult the Lenel Price Book.

2.1.4 Power Indicator

UL294 installations require an external AC power indicator. Connect appropriate trouble reporting devices to AC Fail and Low Battery supervisory relay outputs marked NC, C, NO. Use 22 AWG to 18 AWG for AC Fail and Low Battery reporting. AC Failure will report in five (5) minutes. For a six-hour delay on reporting, cut resistor R1 (not allowed when utilizing a 7 Ah backup battery for UL1076).

1. Locate the “AC FAIL” terminals.

2. Wire an LED indicator according to the following diagram.

AC indicator wiring

3. Install the indicator on the outside of the enclosure. It should be installed using the designated AC knockout.

2.1.5 Cabinet Tamper

Cabinet tamper for all enclosures must be connected and programmed for UL installations and for EN compliance.

2.2 Ground Wiring

Each hardware product must be grounded to provide EMC protection, personnel safety, and signal reference for devices which communicate with each other. Grounding provides a good shield against external transients. See the installation manuals for the grounding point of each product. (See 5 UL Certified Installations for additional detail and/or individual device manuals.)

There are two types of circuit grounds in systems using this hardware:

• DC negative

NO CNC NC AC FAILBAT FAIL NOC

LED

revision 1 — 15


• Safety ground

2.2.1 DC Negative

The DC ground provides signal reference for devices to communicate. It is the DC return from the power supply.

2.2.2 Grounding System

A grounding system can be viewed as two subsystems: the DC system and the ground system. The DC system consists of all interconnected power supply returns, DC distribution wiring, and load devices. The principal function of the DC system is to provide signal reference for communication. The ground system consists of all chassis grounds for power supplies and other devices, safety grounds, and AC grounds. Ground connection should be made to avoid ground loop problems.

Ideally, there should be ONLY ONE ground return point in a power supply system.

2.2.3 Safety Ground

Safety ground (ground wire of 14 AWG minimum, from fuse terminal block to ground lug) is part of the AC power system. On the NGP hardware, the safety ground (earth) and the DC ground should not be connected together. All methods of electrical grounding are regulated by the National Electrical Code (NEC) as outlined in Article 250. Local regulations are constituted from the NEC and may be more stringent than the national regulation.

The National Electrical Code and other safety regulations require that all equipment chassis and or enclosures be grounded in order to prevent shock hazards. Each device must have a green and yellow (or continuous green) wire safety ground. The function of this safety ground is to provide a redundant path for fault currents and to insure that the circuit breaker will open in the event of a fault. In addition, grounding the enclosure provides a path for EMC dissipation, thus protecting sensitive electronic devices.

For Europe, the color used for the ground wire between connector CN2 of the I/O board and the ground point on the mains terminal block is gray as the product is defined as Safety Class II. It is not allowed to be green and yellow as this would imply its use as a protective earth in a Safety Class I product. It is used only for electromagnetic compatibility (EMC) purposes by connecting the wire to the ground wire of the mains wiring on the mains terminal block within the product.

2.3 Input Wiring

Inputs require twisted pair wires. An end-of-line (EOL) resistor terminator is required for each supervised alarm input. Both supervised and unsupervised alarm inputs can support single or multiple contacts per loop. Connect normally closed (NC) contacts in series and normally open (NO) contacts in parallel.

16 — revision 1


2.4 RS-485 Communication Wiring

Proper wiring for RS-485 communication interfaces is critical for successful system turn-up and operation. The following guidelines apply for all RS-485 wiring.

1. Use low capacitance shielded cable with a twisted pair, characteristic impedance 120 ohms (Belden 9842 or equivalent) for the main RS-485 run.

2. Keep the main run maximum end-to-end distance below 4000 feet.

3. Use daisy chain configuration, NOT star configuration, to connect devices.

4. Use shielded 22 AWG cable with 2 twisted pair (Belden 9502 or equivalent.) for down leads (drops or stubs).

5. Keep down leads as short as possible (no longer than 10 feet).

6. Terminate cables with RS-485 terminators when necessary.

7. Always use the shield ground connection. Carefully insulate the ground wire for a reliable installation. Use 24 GA plastic sleeving over the ground wire when terminating the cable to the 5-position insulation displacement mating connector.

2.5 Relay Contact Protection

The the door strike relays used by NGP have an expectancy as follows:

• Expected mechanical life: 10 million operations

• Expected electrical life: 100,000 operations

Both the door strike and AUX relays have a contact life in excess of 100,000 operations, assuming the maximum frequency of 1800 operations per hour at the rated load. Lighter loads, and appropriate contact protection, extend relay life.

2.5.1 DC Inductive Load

Contacts for DC inductive loads can be effectively protected using clamp diodes. Select diodes with reverse breakdown voltage 10 times the circuit voltage.

2.5.2 AC Inductive Loads

Contacts for AC inductive loads can be protected using metal-oxide varistors (MOVs.) MOVs are effective when the load voltage is 100V to 200V. (MOVs are also suitable for DC operation.)

revision 1 — 17


MOVs must be installed as close to the load as possible (within a few inches) to be effective. Mounted in this fashion, MOVs can also reduce the effects of EMI on sensitive electronic circuits.

DC SOURCE

AC SOURCE

NC

C

NO

NC

C

NO

FUSE

+

-

LOAD

LOAD

MOV

FUSE

18 — revision 1


3 System Startup Considerations

A system should never be powered up all at once. For successful system startup, the following step-by-step procedures should be performed.

1. Make sure that no power is applied to any system device.

2. Check all wiring and device switch settings.

3. Disconnect all devices from the RS-485 communication line.

4. Power up the NGP. (Check voltage requirement first.)

5. Configure the NGP, and verify that it is working properly.

6. Connect one port of the RS-485 communication line to a downstream device.

7. Power up a dependent device, and verify that it passes its own power-up self-test. (Check voltage requirement first.)

8. Check for ground fault between the dependent device and the RS-485 communication line. If applicable, find the fault and clear it.

9. Connect the dependent device to the RS-485 line and bring it on-line.

10. Verify all functions of the dependent device.

11. Verify the RS-485 line voltage in reference to the DC ground.

12. For each additional dependent device, repeat steps 7 through 11.

3.1 Device Configuration Checks

Common device configuration problems include mismatched baud rates and incorrect serial numbers. The serial number for each device is unique. Check all settings before attempting to bring the device on-line.

System programming must include the order of priority signals described below:

1. Hold-up or panic alarm or duress.

2. Burglar alarm.

3. Burglar-alarm supervision.

4. Industrial supervision where a risk of injury to persons, or damage or destruction of property will not be involved.

5. Other supervisory services.

Items (1) and (2) may have equal priority. Items (4) and (5) may have equal priority.

3.2 Ground Potential Difference Checks Before Connecting

Before a device can be connected to the RS-485 communication line, it must be checked for ground fault. Uncorrected ground fault can damage all devices connected to the RS-485 communication line.

revision 1 — 19


To check if there is ground fault for a new unit, follow the steps below.

1. Apply power to all devices already successfully connected to the RS-485 line.

2. Power up the new unit, but DO NOT connect it to the RS-485 line.

3. Connect the DC ground of the RS-485 line through a 10K limiting resistor.

4. Measure the AC and DC voltage across the resistor. There should NOT be more than 1 volt across the resistor. Otherwise find and clear the fault.

5. Connect the new unit to the RS-485 line if no ground fault is found.

20 — revision 1


4 Maintenance

The most current version of the firmware is shipped with your OnGuard software and was installed during the initial software installation. Each subsequent software release you receive will also include the most current version of the firmware.

4.1 Firmware Updates

Do the following to update the firmware on your system. You must have the “ADMIN” permission level.

1. Install the new version of the OnGuard software.

2. In the Main Alarm Monitor window of the Alarm Monitoring module, right-click on the name of an access panel.

3. Select the Download Firmware choice from the popup menu.

4. OnGuard will initiate the firmware update then perform a full download to the panel (the I/O board and the SOM).

You must update each access panel in the system. Although it is not necessary to shut down the application to perform the updates, note that the selected access panel is placed in a degraded off-line mode during the process. During this process, the readers connected to the panel are put into their door fallback mode, which is configured in System Administration. It is strongly recommended that you perform the update on the panel during a time when no one will be accessing it.

Firmware can be simultaneously downloaded to multiple panels at once. However, it is recommended to do so one at a time to prevent any problems from occurring until you become familiar with the impact on system performance.

Firmware Versions

Module Version

NGP-2200/2220/3300/3320 Controller 1.0.xxx (x = numeric digit 0-9)

NGP-1100 16 Input Control Module 1.0

NGP-1208 8 Output Relay Control Module 2.0

NGP-1320 Dual Door Interface Module 1.4

120-3633L Worldwide Modem GV3D001183

NGP Command Keypad 1.0

revision 1 — 21


5 UL Certified Installations

For UL Installations, the central supervisory station equipment must be UL listed to one of the following standards:

1. Standard for Office Appliances & Business Equipment, UL 114

2. Standard for Information-Processing & Business Equipment, UL 478

3. Standard for Information Technology Equipment, UL 60950

For UL Installations, use UL Listed information technology equipment. The computer minimum platform requirements are as follows.

• Intel Pentium 4 dual core processor

• 3.4 GHz clock speed

• 1 GB RAM

• Minimum of 20 GB for System and 6 GB for OnGuard database and applications

• DVD+/-RW drive

• One (1) USB port

• Operating systems:- Windows Server 2008 x64 R2 with SP2- Windows 7 Professional x64 bit operating systems v6.0

• Microsoft SQL Server 2008 (32 and 64-bit) or SQL 2008 Express V10.0.3

• OnGuard 2010 Technology Update (6.4) using NGP Hardware Installation Guide (55-6000E) revision 1.017

• NEC ExpressCluster Software X R2 fault tolerant software

• NGP firmware version: 1.0.xx

Equipment must be installed in a temperature controlled environment, maintained between 13 to 35°C (55 to 95°F) by the HVAC system. Twenty-four hours of standby must be provided for the HVAC system.

In addition to the main power supply and secondary power supply that are required to be provided at the central supervisory station, the system must be provided with an uninterruptable power supply (UPS) with sufficient capacity to operate the computer equipment for a minimum of 15 minutes. If more than 15 minutes is required for the secondary power supply to supply the UPS input power, the UPS must be capable of providing input power for at least that amount of time. A means for disconnecting the input to the UPS while maintaining continuity of power to the automation system must be provided, in order to perform maintenance and repair service.

The UPS must comply with the Standard for Uninterruptable Power Supply Equipment, UL 1778.

Be sure to use the recommended cabling, which is the shielded wiring required for use on all modules.

Communication circuits and network components connected to the telecommunications network shall be protected by secondary protectors for communication circuits. These protectors shall comply with the Standard for Secondary Protectors or Communications Circuits, UL 497A. These protectors shall be used only in the protected side of the telecommunications network.

22 — revision 1


Signal line transient protection complies with the standard data communication and fire alarm inputs, UL497B, with a maximum marked rating of 50V.

Supply line transient protection complies with the standard for transient voltage surge suppressors, UL 1449, with a maximum marked rating of 330V.

A totally metal enclosed Class 1 Wiring system (i.e., Conduit) is required for mains earth (Safety) grounding.

Do not exceed 1000 receiver accounts for UL.

The system is to be installed within a protected premise, and the operating temperature range must be 0° to 49°C (32° to 120°F).

This system must be installed in accordance with the National Electrical Code (NFPA 70), and the local authority having jurisdiction. If you are located in Canada, refer to the Canadian Electrical Code.

Failure of the main computer system, hard disk, and alarm monitor must be programmed to failover to the backup system, and indicate an audible, or obvious visual indication.

A fault tolerant system may be used in lieu of complete duplication of the system if every component in the fault tolerant system, including the software and power supply, is duplicated.

All OnGuard system solutions that are to be UL1076 compliant systems must also meet the requirements specified in Section 25A of the UL1076 (Proprietary Burglar Alarm Units and Systems Standard for Safety). This requirement outlines the need for host monitoring redundancy. Host monitoring redundancy can be accomplished in many ways, but the standard is clear as to receiving equipment methods, recovery time, surge suppression and system configurations. Contact Lenel if configuration assistance is required.

All inputs must be supervised for UL1076 installations.

Priority features (alarm, loss of line voltage, opens, shorts, etc.) must be programmed for an audible and a visual indication at the central supervisory station equipment, and to create a printout. The condition must be recorded. This indication shall not be silenced without acknowledgement.

Bypass of protective features, such as auto-bypass for forced arm, must not be programmed for UL.

Firmware version 1.0.xxx is firmware that is embedded (installed) in conjunction with the NGP for suitability as “Encrypted Line Security Equipment.” (See NIST Certificate number #1496 at http://csrc.nist.gov.)

HVAC rated modules were not evaluated by UL for Lenel OnGuard UL294/UL1076 product listing.

5.1 Power

5.1.1 CSSE Equipment Requirements

The standby power system for the HVAC system may be supplied by an engine driven generator alone. Use of a standby battery is not required.

revision 1 — 23

http://csrc.nist.gov

http://csrc.nist.gov


5.1.2 Premises Equipment Requirements

All external interconnecting devices must be UL Listed and powered by UL Listed access control or proprietary burglar alarm power limited power supply. Do not route high voltage (110 V) lines in the same conduit or harness as low voltage lines.

5.2 Typical Combinations for UL Installations

The following combinations must be used in a UL type installation with OnGuard software version 6.4.xxx, which is approved for use. For UL certification, a UL Listed power supply, either NGP-UL, LNL-AL400ULX or LNL-AL600ULX-4CB6 with additional hardware mounted in LNL-CTX or LNL-CTX-6 enclosures, or IPSU 120-3650L must be used.

Multiple combinations of Lenel access hardware can be used within the UL approved power supply and enclosure.

Intelligent System Controller Combinations

Any individual board would be supported NGP-22xxyyy or NGP-33xxyyy (where x represents any number 0-9 and y represents any alphanumeric character that reflects applications enabled and type of power supply/enclosures within a NGP-UL single enclosure.

1. NGP-22xxyyy or NGP-33xxyyy Intelligent System ControllersWWM Worldwide Modem (Not evaluated for UL1076 applications.)NGP-1100 (one (1) unit)NGP-1208 (up to two (2) units)

Reader Interface Module and Gateway Combinations

Any individual board would be supported (NGP-1320) as well as any combination of the following boards within a single LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies.

Input/Output Module Combinations

Any individual board would be supported (NGP-1100 or NGP-1208) as well as any combination of the following boards within a single IPSU, LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies.

Combinations of the following boards within a single IPSU enclosure (model 120-3650L):

1. NGP-1100 Input Control Module (one (1) unit)NGP-1208 Output Control Module (up to three (3) units)

Combinations of the following boards within a single LNL-CTX or LNL-AL400ULX power supply unit:

1. NGP-1320-UMP Reader Interface module (up to two (2) units)

2. NGP-1100-UMP Input Control Module (up to two (2) units)

3. NGP-1108K-UMP Input Control Module (up to two (2) units)

4. NGP-1216K-UMP Output Control Module (up to two (2) units)

24 — revision 1


Combinations of the following boards within a single LNL-CTX-6 or LNL-AL600ULX-4CB6 power supply units:

1. NGP-1320 Reader Interface module (up to six (6) units)

2. NGP-1100-UMP Input Control Module (up to six (6) units)

3. NGP-1108K-UMP Input Control Module (up to six (6) units)

4. NGP-1216K-UMP Output Control Module (up to six (6) units)

UL Evaluated Readers

The following readers have been evaluated by UL for use with the OnGuard system.

• Lenel Magstripe Reader LNL-2020W



• SmartID MIFARE 8-bit PIN pad 8031DSCM-LNL-3020

• SmartID MIFARE 8030DSCM-LNL-3010

• HID Prox 8-bit PIN pad 5355-AGK09

• HID Prox 5395-CG100

• HID Prox 4-bit PIN pad 5355-AGK00

• iCLASS 6100CKN0000L

• iCLASS 8-bit PIN pad 6130BKN00079G3L

• iCLASS 6120CKN0000L

• iCLASS/HID Prox 8-bit PIN pad 6136AKN00079G3L

• iCLASS/HID Prox 6125CGN0007G30L

• Lenel OpenCard 8-bit PIN pad LNL-XF2110D-P2

• Lenel OpenCard LNL-XF1050K

• Lenel Prox with PIN pad LPKP-6840GRMP

• Lenel Prox LPMM-6800GRMP

• Lenel Prox LPSR-2400GRMP

• Lenel OpenCard LNL-XF1500D-S

• G-Prox II switch plate 100-5434

• G-Prox II mullion Wiegand keypad 100-5436

• G-Prox II switch plate with Wiegand keypad 100-5431

• G-Prox II mullion 100-5439

• G-Prox II mullion arming station 100-5435

• G-Prox II switch plate arming station 100-5430

• Card formats from 26 to 200 bit evaluated

revision 1 — 25


5.2.1 Acknowledgement Signal

For remote arming (or switching the protection mode at the protected area), the system must be programmed to provide a visual and/or audible signal at the keypad to indicate to the attendant at the protected area that the confirmation closing signal has been received by the central supervising station.

5.2.2 System Testing

For UL294 and UL1076 compliance, a general system test must be performed at least once per year.

26 — revision 1

ENCLOSURE


6 NGP Enclosure

NGP enclosures (NGP-UL or NGP-CE) use the mounting holes along the edge of the panel to securely install the NGP-2200, 3300, 2220, or 3320 in the enclosure. In a single enclosure, one NGP controller can be mounted along with one worldwide modem, one NGP-1100, and up to two NGP-1208 modules.

Panel positioning within enclosure

The dimensions of the enclosure, with the cover closed, are H 537 mm x W 343 mm x D 106 mm (H 21.14 x W 13.50 x D 4.17 inches).

NGP

revision 1 — 29

Next Generation Panel

6.1 Anti-attack Bushing Cap

An anti-attack bushing cap covers a rear tamper spring. It fits inside an O ring bushing located in the cabinet’s rear wall anti-tamper spring knockout. Leave the O ring bushing and cap in place if the rear tamper is not used.

If the rear tamper is used:

1. Remove the cap and the O ring with the edge of a flat screwdriver.

2. Discard the O ring.

3. Align the cap for the tamper spring and knockout hole on the cabinet back.

4. Screw the cap into the mounting surface.

5. Place the control cabinet over it, allowing the rear tamper spring to fit inside the cap. The cap will fit into the cabinet’s tamper spring knockout hole.

6. Secure the cabinet to the mounting surface.

6.2 Mounting an Enclosure

On dry wall, use 1/8” hollow wall, expansion anchors. Unscrew the screws from the anchors. Mark the mounting holes. Force a starter hole in each mark with a sharp tool. Hammer the anchors into each hole. Align the box mounting holes over the anchor holes and screw in the anchors until tight.

On a concrete surface, hold the control box on the mounting surface. Mark the mounting holes. Use a hammer drill with a 3/16” carballoy drill bit and make 1" deep holes in each marking. Insert a # 6-8 plastic anchor in each hole and hammer them in. Use # 8 X 1", Phillips, wood screws to screw into the plastic anchors and mount the box.

30 — revision 1


NGP controller enclosure dimensions

GG

D

D D

D

E

DDD

DDD

E E

F F

N

N

N

KK

K

H

J

K

N

D

D

N

D

N

NN

N

H

N

G

150mm ±0.50[5.91in ±0.02]

150mm ±0.50[5.91in ±0.02]

47.12mm[1.86in]

174.12mm[6.86in]

130m

m ±

0.5

[5.1

2in

±0.0

2]

10.92mm (5 POS)[0.430in]

50mm ±0.5[1.97in ±0.02]

230m

m±0

.5[9

.06i

n ±0

.02]

254.00mm[10.000in]

140.00mm[5.51in]145mm ±0.5

[5.71in ±0.02] 224.92mm

[8.86in]

97.79mm[3.85in]

59.0

8mm

[2.3

3in]

232.

46m

m[9

.15i

n]

J

N

J

6.48

mm

[0.2

55in

]

10.0

0mm

[0.3

94in

] R2.55mm

[0.1004in]

11.00mm

[0.433in]

160.

51m

m[6

.32i

n]14

9.84

mm

[5.9

0in]

40.0

0mm

[1.5

7in]

10.1

4mm

[0.4

0in]

238.

53m

m[9

.391

in]

130.

00m

m[5

.12i

n]46

3.43

mm

[18.

245i

n]43

8.15

mm

[17.

25in

]46

3.43

mm

[18.

25in

]

65m

m±0

.50

[2.5

6in

±0.0

2]16

3.12

mm

[6.4

2in]

170m

m±0

.5[6

.69i

n ±0

.02]

212m

m±0

.5[8

.37i

n ±0

.02]

55mm ±0.50[2.17in ±0.02]

15.00mm[0.59in]

60.36mm[2.38in]

100m

m ±

0.5

[3.9

4in

±0.0

2]65

mm

±0.

50[2

.559

1in

±0.0

197]

89.0

mm

±1.

0[3

.504

in ±

0.03

9]81

.00m

m[3

.19i

n]

12.7

0mm

[0.5

0in]

469.

9mm

[18.

5in]

12.7

0mm

[0.5

0in] 25.00mm

[0.98in]

119.9mm ±1.0[4.721in ±0.039]

15.37mm[0.61in] 45.87mm

[1.81in]63.40mm[2.50in] 119.92mm

[4.72in]239.84mm

[9.44in]

revision 1 — 31


32 — revision 1

NEXT GENERATION PANEL


7 Overview of the NGP

This installation guide is intended for use by technicians who will be installing and maintaining the Next Generation Panel (NGP).

The NGP provides a solution for access control and intrusion detection. It consists of two boards; the I/O board and the system on module (SOM) board. The I/O board, the larger of the two, contains the power supply and all field wiring connections. The SOM, the smaller mounted board, contains the main CPU and memory.

The event log buffer and the real time clock are stored in battery-backed memory. Each reader port can accommodate a reader that utilizes Wiegand Clock/Data or Data 1/Data 0, magnetic stripe, LED control, and buzzer control.

Twelve supervised inputs (excluding tamper and power monitor) are provided for door sense, reader tamper, or request to exit as well as the four dedicated intrusion circuit supervised inputs.

7.1 Interfaces

The NGP interfaces upstream with the access control software on a host system via Ethernet. It is capable of Dual Signal Line Transmission methods which for all UL installations will require that two independent Internet service providers (ISPs) must be used for one for each network connection.

The modem connection may be used to communicate to central station receivers. A connected worldwide modem may be used for reporting SIA and contact ID formatted alarms to the central supervisory station (SIA and contact ID have not been evaluated by UL).

Configuration data and event/status reports are exchanged with the host via the Ethernet ports.

7.1.1 Model Numbers

The panels are available in the following configurations:

• NGP-2200: Medium controller, no onboard doors, single Ethernet port

• NGP-2220: Medium controller, two onboard doors, single Ethernet port

• NGP-3300: Enterprise controller, no onboard readers, dual Ethernet support

• NGP-3320: Enterprise controller, two onboard readers/doors, dual Ethernet support

* These models were evaluated by UL.

Panel options

Panel without intrusion, with enclosure (US 120 VAC internal transformer)

Panel without intrusion, with enclosure (CE 220 VAC internal transformer)

Panel with intrusion, without enclosure

Panel with intrusion, with enclosure (US 120 VAC internal transformer)

Panel with intrusion, with enclosure (CE 220 VAC internal transformer)

NGP-2220UL* NGP-2220CE NGP-2220I* NGP-2220IUL* NGP-2220ICE




revision 1 — 35


7.1.2 System Capacities

7.2 The NGP Board

Parts list:

• NGP PCB assembly, which consists of the I/O board and the SOM (quantity = 1)

• Two positional terminal plug-in block (quantity = 7)

• Three positional terminal plug-in block (quantity = 10)

• Four positional terminal plug-in block (quantity = 8)

• End of line resistors 1k ohm, 1% (quantity = 24)

• Push-fit terminal tab adapters (quantity = 2)

• Battery cable (quantity =1)

• Battery bracket (quantity = 1)

• Screws for battery bracket (quantity = 2)

• Strain relief for power cable (quantity = 1)

• Terminal block cover (quantity = 1)

• Lock (quantity = 1)

• Machine screws for securing the cover (quantity =6)

• Enclosure (depending on option ordered)

• Transformer (depending on option ordered)

Attribute NGP-2220/NGP-2220I NGP-3320/NGP-3320I

Number of unique badges 249,999 499,999

Number of retained events in event log 50,000 50,000

Number of doors (base board and dual door controllers)

66 130

Total number of system inputs 512 1024

Total number of system outputs 256 256

Ethernet ports 1 2

RS-485 SNAPP bus ports 4 4

Number of unique access levels 32,000 32,000

Maximum access levels per badge 128 128

Number of different types of events 500 500

Number of distinct schedules 250 250

Number of distinct holidays 255 255

36 — revision 1


The NGP board

CN32

+WW Modem

Interface

LINK1

LINK2

LINK3

LINK4

LED1

LED2

LED11

LED3SNAPP1

LED4SNAPP2

LED6SNAPP3

SNAPP4 LED5

LED7 LED8LED9LED10

LINK5

SW1RESET

SW3

IP

I/O BOARD

LED13

LED12

CN38

CN39

CN40

CN41

CN35

SOM BOARD

BP4

J24

CN1

CN2

CN3

CN4

CN5

CN6

CN7 CN8 CN9 CN10 CN11 CN12 CN13 CN14 CN15 CN16 CN17 CN18 CN19 CN20

CN21

CN22

CN23

CN24

CN25

CN26

CN27

CN37

120V

140

140

CNC

NOC

NO0

SW

NO C NC AX 0 RT DR 0 TR BZ 14 GR RD D1 D0 0 A B NO C NO C NC AX 0 RT DR 0 TR BZ 14 GR RD D1 D0 0 A B NO C

14#1

0#2

#30

#414

A+0

B–14

A+0

B–14

A+0

B–14

A+0

B–V

0

2

12

3

12

3

4

12

3

12

12

1 2 3 1 2 3 1 2 3 1 2 3 1 2 3 4 1 2 1 2 1 2 3 1 2 3 1 2 3 1 2 3 1 2 3 4 1 2 1 2

1

2

34

1

2

3

1

2

34

1

2

34

1

2

34

1

2

34

1

2

1

250 mm (9.84 in)16

0 mm

(6.30

in)

97.79 mm (3.85 in)

174.12 mm (6.86 in)

224.92 mm (8.86 in)10

.14 m

m (0

.40 in

)

149.8

4 mm

(5.90

in)

47.12 mm (1.86 in)

119.92 mm (4.72 in)

239.84 mm (9.44 in)

174.12 mm (6.86 in)

revision 1 — 37


8 Installation

To install the NGP, perform the installation procedures described in the following sections, in the order in which they are presented.

1. Wire the device for communication.

2. Wire readers.

3. Wire the input circuits.

4. Wire the relay circuits.

5. Supply power to the panel.

6. Remove the plastic safety strip from the memory backup battery located on the SOM.

7. Configure the correct settings.

8. Set the board for the desired IP addressing.

8.1 Wiring

Refer to the following for wiring of the NGP.

38 — revision 1


Wiring diagram

Notes: The 1K EOL resistors and NO contacts on the supervised inputs are shown as a typical configuration only and do not restrict the actual use of these inputs in the field.

The battery leads at CN32 must be routed away from power limited circuits. Maintain 0.25 inches (6 mm) spacing between non-power limited (that is, battery leads and AC Mains) and power limited wiring.

8.1.1 Communication Wiring

The controller communicates to the host via Ethernet. Communication of configuration data and status reports via modem is currently not supported.

The downstream communication ports are 2-wire RS-485 interfaces which can be used to connect additional I/O panels. The interface allows multi-drop communication on a single bus of up to 4000 feet (1200 m). Use twisted pairs (minimum 22 AWG) with an overall shield for communication.

1K

Inpu

t 2In

put 1Input 1

Input 2

0V

Input 3

0V

Inpu

t 3In

put 4

1K

1K

1K

1K1K

1K

1K

Inpu

t 4

+12V

Aux 1 +V output

Aux 2 +V output0V

CSiren Relay

Strobe RelayExternal Tamper

0V

NC

AuxPower

CN00V

SW

V0V0VB -A ++V

EthernetPort 1

+-

To 12V battery

(Power limited to 200mA per port)

EthernetPort 2

3VCoinCell

IP Setting

Term 4

Term 3

Term 2

Term 1

12VDC Input

18VAC/24VDC Input

0V

NO

Network Interface(OnGuard Host Communications)

CN

1C

N2

CN

3C

N4

CN

5C

N6

CN

43

CN7 CN8 CN9 CN10 CN11

CN12

CN13 CN14 CN15 CN16 CN17 CN18 CN19 CN20

CN

21C

N22

CN23

CN24

CN25

CN26

CN

27

12

123

123

12

12

12

1234

1 2 3 1 2 3 1 2 3 1 2 3 1 2 3 4 1 2 1 2 1 2 3 1 2 3 1 2 3 1 2 3 1 2 3 4 1 2 1 2

21

4321

4321

4321

4321

321

4321 +V

Relay optionif fitted

RS4

85Bu

s 1

RS4

85Bu

s 2

RS4

85Bu

s 3

RS4

85Bu

s 4

VBU

S

Panasonic p/n CR2354

To secure battery use bracket p/n 28005B and2 off 8-32 screws from the supplied accessories kit.

14VSND

18VAC/24VDCPower Indication LED

ConfigFactory set : do not adjust

OSDP1 Comms LED

OSDP2CommsLED

MicrocontrollerStatus LEDs

Speed LEDs(10Mbits/100Mbits)

Link (Activity) LEDLink (Activity) LED

Test

Add shunt to Term 1~4 if 120Ω termination is required

SNAPP 4 LED

SNAPP 2 LED

SNAPP 3 LED

SNAPP 1 LED

SNAPP LEDs indicate bus comms

USB 2Dual Port

CN

37

CN32

+

RED

BLACK

WW ModemSocket

SOM Status LEDs

0VB -A ++V0VB -A ++V0VB -A ++V

Buzz

er

AccessReader 1

0V+VG

reen

LED

Red

LED D

1

D0

D1

D0

N0 C

EgressReader

Aux Relay

StrikeRelay

Door Controller 1

1K

InputInput

Aux

RTE0V

DR TR0V

Input Input

N0 C

NC

1K

1K

1K

1K 1K

1K 1K

Buzz

er

AccessReader 2

0V+VG

reen

LED

Red

LED D

1

D0

D1

D0

N0 C

EgressReader

Aux Relay

StrikeRelay

Door Controller 2

1K

InputInput

AuxR

TE0V

DR TR0V

Input Input

N0 C

NC

1K

1K

1K

1K 1K

1K 1K

Non Power Limited

Power Limited

Pow

er L

imite

d

Pow

er L

imite

d

Power Limited Power Limited

Power Limited Power Limited

Battery leads to routed directly under board

Maintain 0.25in spacing between power and Non Power Limited circuits

revision 1 — 39


8.1.2 Reader Wiring

Each reader port supports Wiegand or magnetic stripe. Voltage at the reader port is passed through from the input voltage of the controller and is limited to 250 mA.

The reader supply voltage is 14 VDC. Readers that require different voltage should be powered separately. These readers may be connected and powered through the dual door interface module. Refer to the reader manufacturer specifications for cabling requirements.

Wiegand reader wiring

For magnetic stripe card readers, the wiring for Clock/Data0 and Data/Data1 is reversed from typical Access (LNL) series wiring.

Magnetic stripe reader wiring

CN10/CN17

CN11/CN18BZ

+GR

RDD1

D00

12

31

23

4

Buzzer

Ground

+14V

Red LEDData1Data0

Green LED

CN10/CN17

CN11/CN18

BZ+

GRRD

D1D0

0

12

31

23

4

Buzzer

Ground

+14V

Red LED - not connectedData

Clock

Green LED

40 — revision 1


Wiring In and Out readers

8.1.3 Keypad Wiring

The LCD keypad can be connected to the NGP and used for programming. Connect the keypad to the RS-485 bus on the NGP.

Keypad wiring diagram

CN10/CN17 CN11/CN18 CN12/CN19

BZ 14 GR RD D1 D0 0 A B

1 2 3 1 2 3 4 1 2

Buzz

er 0V

+14V

Red L

ED D1 D0 D1 D0

Gree

n LED

Data1Data0BuzzerLEDPowerGround

Reader (In)

Reader (Out)

Data1Data0

BuzzerLED

PowerGround

GroundBAPower+

A+0

B–

1

2

34RS-485 bus

on NGP(CN23-CN26)

Keypad terminal block

1 432 5 6A B 0V BUS OUT+ V

revision 1 — 41


An external reader may also be used by connecting it to the keypad.

Keypad and external reader wiring

This configuration is only supported using a keypad that specifically supports external readers. Note that there is no connection for reader buzzer and LED.

Only the first two card formats assigned to the panel can be used on the NGP LCD keypads with attached readers.

8.1.4 Input Circuit Wiring

Typically, these inputs are used to monitor door position, request to exit, or alarm contacts. Input circuits are supervised. The input circuit is able to report a condition of “Fault” for the status of the circuit, which appears as an “Alarm active” event for supervised conditions.

A supervised input circuit requires a resistor be added to the circuit to facilitate proper reporting. The standard supervised circuit requires 1K Ohm, 1% resistors and should be located as close to the sensor as possible.

GroundBAPower+

A+0

B–

1

2

34

RS-485 bus on NGP

(CN23-CN26)

Keypad terminal block

1 432 5 6D1 D0

1 432 5 6A B 0V BUS OUT+12V0V 0VPT1 PT2 V

Data1Data0Buzzer — no connectionLED — no connectionPowerGround

Reader

42 — revision 1


8.1.5 Relay Circuit Wiring

All relays are dry contact.

The relays for siren and door strike have a Common pole (C), a Normally Closed pole (NC), and a Normally Open pole (NO). When you are controlling the delivery of power to the door strike, the Normally Open and Common poles are used. When you are momentarily removing power to unlock the door, as with a mag lock, the Normally Closed and Common poles are used. Check with local building codes for proper egress door installation.

8.1.6 Power

The NGP requires 18 VAC or 24 VDC for input power at CN3, or 12 VDC at CN1 (24 VDC and 12 VDC input power were not evaluated by UL). When powering the board from 12 VDC, the on-board battery charger will not be used and the lead-acid backup battery should not be connected to the NGP. The power supply providing the 12 VDC must have its own backup source.

The maximum input current is 2.7 A. The gauge is dependent on the length of the wire. For UL installation, the NGP must be powered by the internal 18 VAC transformer that uses 20 AWG secondary wires. The NGP can be powered by an internal 18 VAC transformer that uses 20-gauge secondary wires, as shown.

NGP 110/220 VAC Power wiring diagram

Output 30 VDC rating

Siren relay 1 A

Strobe relay 1 A

Strike relay 5 A

Aux relay 1 A

Wiring Indication

Gnd Stud

Red transformer wires

Connections for AC wiring

revision 1 — 43


Power connectors

Maximum lengths for wiring

I/O Description Connection Maximum length of 22AWG wire (in feet)

Maximum line resistance (in Ohms)

13.2 V supply output CN3-1CN3-3CN10-2CN17-2CN21-1CN23-1CN24-1CN25-1CN26-1

300 approximately 4.8

Supervised inputs CN8-1CN8-3CN9-1CN9-3CN15-1CN15-3CN16-1CN16-3CN21-2CN21-4CN22-1CN22-3

500 approximately 8

5 A @ 24 VDC relay output (assume 15% voltage drop)

CN7-1 (NO)CN7-2 (C)CN7-3 (NC)CN14-1 (NO)CN14-2 (C)CN14-3 (NC)


1 A @ 24 VDC relay output (assume 15% voltage drop)

CN4-1 (C)CN4-2 (NC)CN4-3 (NO)CN5-1(C)CN5-2 (NC)CN13-1 (NO)CN13-2 (C)CN20-1 (NO)CN20-2 (C)


CN1

CN2

120V 2

12

3

1+12V12 VDCInput

18 VAC/24 VDCInput

0V

44 — revision 1


Note: These specified ranges have been verified by UL. Note that if you run a longer wire, it is not verified by UL.

This equipment must be permanently connected to a mains fused spur (3 A or 5 A) using 3-core cable with

each core being no less than 0.75mm2 (18 AWG). The mains cable should be clamped securely with the cable clamps provided within the equipment/installation kit. Knockouts are provided on the top, bottom and sides of this equipment and these are intended for conduit or cable glands. As a mains switch is not provided on the equipment, a readily accessible disconnect device shall be incorporated in the building installation wiring. Where there is doubt as to the phase of this wiring, the device, when operated, will disconnect both poles simultaneously.

Warning: For continued protection against risk of fire, replace the mains fuse only with the same type and rating of fuse.

The Aux. DC supply output is a Class 2 Power Limited circuit.

* 24 VDC and 12 VDC input were not evaluated by UL.

** This DC Power Supply Rating is for all the current requirements, including recharging the battery.

Board protection is provided by resettable fuses which are not replaceable.

All wiring in this enclosure is required to be UL compliant. All installation wiring within this equipment cabinet should utilize plastic cable ties to bundle cables and attach to designated cabinet cable mounting locations to provide strain relief for the cable harness.

Mains Supply

Item North America product

European product Australian/New Zealand product

External power source 120 VAC +10% -15%, 60Hz

230 VAC +10% -15%, 50Hz

240 VAC ±10%, 50Hz

Input current rating (AC)

600 mA 250 mA 250 mA

Mains fuse T630 mA 250 V, UL Listed

T400 mA 250 V T400 mA 250 V

Aux DC Supply

Item Mains powered unit +24 VDC input* +12 VDC input*

Output voltage (DC) 14 V ±5% 14 V ±5% 12 V ±5%

Standby battery 7 Ah or 18 Ah 7 Ah or 18 Ah —

Maximum recharge time

24 hours 24 hours —

DC power supply rating**

2.4 A 2.4 A 1.2 A

Battery charge limit 1.2 A 1.2 A —

Quiescent current 140 mA 140 mA 200 mA

revision 1 — 45


Disposal of batteries should be according to the local laws and regulations of your region. Contact your local waste management office for information on battery recycling or disposal.

If you are not able to identify the applicable rules in your area, check the instructions which will be available from the battery manufacturer.

Ground all enclosures in accordance with NFPA 70 and Canadian Electrical Code, Part I.

8.1.7 Power Setup

Power for the NGP controller should be configured in System Administration. This is accessed in the Access Panels folder on the NGP form on the Power sub-tab. Configure the power as follows:

• Brownout mode: Alarm and report

• Brownout voltage (V): 10.00

• Battery size (Ah): 18

• Select Check for battery.

• Clear the Enable battery tests check box.

• Test time: 10 sec

• Low load test period: 3 min

• High load test period: 20 hr

• Low voltage (V): 11.70

• Warning voltage (V): 11.40

• Cutoff voltage (V): 10.20

• Very low voltage (V): 9.00

• Excess charge voltage (V): 16.00

• Cutoff time: 10 sec

• No current (mA): 17

• Excess power state discharge current (A): 1.200

8.2 Memory Backup Battery

Remove the factory-installed plastic safety strip from the memory backup battery. This plastic strip prevents the battery from being effectively seated. The battery will not function properly until the plastic strip is removed.

8.3 Installing Jumpers

The following chart describes each jumper.

Jumper Description

CN37 External LED indication for AC power (to be wired to the outside of the enclosure)

CN38 Controls SNAPP 1 termination. 120-ohm termination is added across the bus when the shunt jumper is installed on the pin header.

46 — revision 1


Resetting the Controller

The reset button is located on the I/O board.

1. To reset the I/O board, press SW1 (indicated by “RESET” in the silk-screen on the I/O board).

8.4 Web Configuration

Before using the panel, additional configuration is required.

1. Using a browser, access the controller by going to its IP address. If the board has never been programmed, the default IP address is https://169.254.1.100 or https://169.254.1.200 when directly connected to its primary Ethernet port (when connected to the secondary Ethernet port, https://169.254.1.201). Otherwise, use the programmed static IP address, or the address obtained from the DHCP server. You may also obtain the IP address by viewing it from a keypad, if there is one connected.

Note: A warning may appear initially when trying to log in that states a problem with this Web site’s security certificate. Although it is not recommended, proceed to the Web site. (For more information, consult your browser’s online help or system administrator for assistance.)

2. Enter the user ID (service ID), 000000. For the password, the service PIN, 2482, needs to be entered to view the page. Once logged in, you may view and edit settings for the panel.

3. On the Network Settings page,

a. Select the type of addressing for the primary interface. Enter the IP address, network mask, and network gateway. This information can be obtained from your system administrator.

b. If you are not planning on using a secondary interface, select Disable from the drop-down. Otherwise, select the type of addressing for the secondary interface. Enter the IP address, network mask, and network gateway. For the secondary interface, you should configure the panel for a network that is different from the primary.

c. Click [Update].After updating the network settings, you will need to reconnect to the panel using the new information.

4. On the Host Communications Configuration page,

a. For the primary and secondary paths, Ethernet is supported. If it is not already selected, select Ethernet from the drop-down.




CN35 If the panel needs to be started on battery only, without ever having AC or DC power, this connector should be momentarily shorted.

Jumper Description

revision 1 — 47


b. For the Ethernet configuration port number, enter 3001.

c. Do not change the settings under Serial Configuration. They do not apply at this time.

d. Click [Update].

5. On the Authentication Configuration page, the settings that appear here are used to configure the access panel in System Administration.

a. Type in a number for the panel code.

b. Type in a number for the password.

c. The serial number cannot be changed.

d. Click [Update].

6. On the License Update page, the panel license information is displayed. You may update the license by browsing to the license file. Then click [Update].

48 — revision 1


9 Status

There are LEDs on the I/O board and SOM board to indicate status.

9.1 NGP Board LEDs

The following chart describes the purpose of each LED on the I/O board.

LEDs 1 through 10 will be switched off when the enclosure is closed.

9.2 SOM Board LEDs

The following chart describes the purpose of each LED on the SOM board.

NGP I/O board LED

Description

LEDs 1 and 2 During normal operation, the heartbeat is indicated by a one second blink rate on LED 2.

During firmware upgrade...

• When LED 1 and LED 2 are both ON, the board is in monitor program mode (bootloader mode).

• When LED 1 is ON and LED 2 is off, programming (flash) firmware is in progress.

LED 3 Orange LED indicates communication occurring on SNAPP port 1.




LED 7 Green LED indicates link and activity on primary Ethernet port (Eth0).

LED 8 Yellow LED indicates speed on primary Ethernet port (Eth0).

LED 9 Green LED indicates link and activity on secondary Ethernet port (Eth1).

LED 10 Yellow LED indicates speed on secondary Ethernet port (Eth1).

LED 11 Not applicable

LED 12 Green LED indicates the presence of power to the board at connector CN2.

SOM board LED

Description

Power LED Green LED indicates SOM power.

Status 1 Yellow LED, along with the green power LED, indicates initialization.

revision 1 — 49


Status 2 Red LED is off. Currently not defined.

SOM Errors

Status/error LED blink pattern

Waiting for input Both Power and Status 1 LEDs blink rapidly (4Hz)

Progress Both Power and Status 1 LEDs blink slowly (1Hz)

Error Codes Group G

ERROR_G2… ERROR_G8

The error code displays in a loop.

1. Both LEDs blink for 0.5 second and turn off for 0.5second.

2. The yellow LED turns ON and the green LED blinks (2-8 times) and then turns off.

3. The cycle repeats.

Error Codes Group Y

ERROR_Y2… ERROR_Y8

The error code displays in a loop.

1. Both LEDs blink for 0.5 second and turn off for 0.5 second.

2. The green LED turns ON and the yellow LED blinks (2-8 times) and then turns off.

3. The cycle repeats.

Error code Error

ERROR_G2 Bootstrap: SDRAM Test failed (only first 256KB)

ERROR_G3 Bootstrap: Bootloader CRC Error

ERROR_G4 Bootstrap: Failed to load Bootloader

ERROR_G5 System cannot boot. Retry count reached

ERROR_G6 Bootloader: Failed to load Linux Kernel (CRC error, Flash Write error)

ERROR_G7 Bootloader: Loading Emergency RootFS

ERROR_G8 Bootloader: Corrupted Root File System

ERROR_Y2 Bootloader: SDRAM Test failed

ERROR_Y3 Read BootFlags failed

SOM board LED

Description

50 — revision 1


9.3 Replace Battery

The event log buffer and the real time clock are backed up by a 3 V battery. Without power being applied to the controller, the battery will retain events and transactions for up to one year.

This battery should be replaced annually to insure that proper backup functionally is maintained. Remove the insulator from the battery holder after installation. Replacement battery: Panasonic CR2354 Lithium coin cell battery.

Caution: Battery may explode if mistreated. Do not recharge, disassemble or dispose of in fire. Follow local code for proper disposal of used lithium battery.

WarningWhen changing the lithium battery, replacement must be a Panasonic CR2354 only.

revision 1 — 51


10 Specifications

The NGP is for use with UL Listed access control power limited power supplies.

These specifications are subject to change without notice.

• Primary Power:

- AC power: 18 VAC ± 10%- DC power: 24/12 VDC ± 10% (Not evaluated by UL)- Maximum input power: 2.7 A- Total current that can be sourced from panel: 1 A.

Note: It is up to the installer to ensure that the sum of the loads on all the supply outputs from the NGP plus the current consumed by the NGP is equal to or less than 1.2 A. The 1.2 A output current from the regulator also includes at least 200 mA to power the I/O board and the SOM. Maximum available output current is 650 mA (example 250 mA for (Reader power) + 400 mA for (SNAPP Ports) = 650 mA total current used. That means the installer has 0 mA available for Aux power devices. Drawing more will cause the output voltage to drop as the system regulator starts to current limit.

- The power applied from the mains to the transformer in the enclosure is 120 VAC for North America (230 VAC for Europe, and 240 VAC for Australia).

• Memory and Clock Backup: Panasonic 3 V CR2354 Lithium coin cell battery

• Wiring

- Ground: 14 AWG, provided in the panel from the fused terminal block to the ground lug- Module Bus (RS-485) Cabling (device communication and power): Recommended: 22 AWG, 4

conductors, shielded twisted pair, 120 impedance, low capacitance, 41 pF/meter or 12.5 pF/foot (such as Belden 9842).

- Maximum Length: Up to 2000 feet (610 m) of cable on a module bus port.

Note: For longer cable distances, or where one cable connects many expansion modules (daisy chained, star wiring configurations are not acceptable), a 120-ohm terminating resistor will need to be installed across A and B communication terminals of the last module on the bus cable.

- Separate Power (or door strike) Wiring: Recommended: 18 AWG, stranded and insulated (2 conductors; color-coded is preferable)

- Inputs/Sensor Cabling: 22 AWG, 2 wires (For electrically noisy environments, use twisted pair, and/or shielded cable.)

- Outputs/Signaling: 22 AWG, 2 conductors

• Reader Cabling: 22 AWG (For Canadian UL Listed installations: 22 AWG), shielded. Maximum for reader data lines: 500 feet (150 m). Maximum for power wiring: 300 feet (91.44 m)

- Basic reader (no LEDs, buzzer control, or tamper): 4 conductors- Reader with LEDs: 6 conductors- Reader with LEDs, plus buzzer and tamper: 9 conductors

• Relays outputs:

- Siren relay, 1 A @ 30 VDC- Strobe relay, 1 A @ 30 VDC- Strike relay, 5 A @ 30 VDC- Aux relay, 1 A @ 30 VDC

52 — revision 1


• Environmental:

Temperature:

– Operating: 0° to +49° C (32° to 120° F)

– Storage: -40° to 85° C (-40° to 185° F)

Humidity: 10 to 85% ± 5% RHNC

• Mechanical:

Dimensions: H 160 x W 250 x D 42 mm (H 6.30 x W 9.84 x D 1.65 inches)

Weight of I/O board and SOM board: 0.47 kg

Weight of accompanying parts:

– Enclosure: 6 kg

– Transformer: 1 kg

– Battery retention bracket: 0.09 kg

– 18 Ahr battery: 5.8 kg

• CE marking

• RoHS compliant

• WEEE

• FCC part 15

• UL294/UL1076 Listed

• ULC Listed

• AES128 certified (Certificate #1496)

revision 1 — 53


54 — revision 1

PERIPHERAL DEVICES


11 16 Input Control Module NGP-1100

The 16 Input Control Module (model series 650-3646) monitors up to sixteen supervised inputs. It communicates to the NGP intelligent system controller on the SNAPP bus (RS-485) and can interface to the NGP-1208 output relay control module via VBUS internal cabinet communications. A maximum of four VBUS output relay expansion modules (for a total of 32 relay outputs) can be supported by one input control module.

The input control module can also monitor four NGP power supply units on its VBUS.

Input control module with VBUS

The NGP-1100 is available separately. It is also sold with a universal mounting plate (NGP-1108-UMP). With the mounting plate, it can be installed in either the LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies.

11.1 Packing List

• 16 Input Control Module (quantity = 1)

• Installation kit which includes:

- Two positional terminal plug-in block (quantity = 2)- Three positional terminal plug-in block (quantity = 10)- Four positional terminal plug-in block (quantity = 1)

Dat

a A

Dat

a B

0V IN9

TB12

TB7 TB1

TB6

(+) 1

2 V

IN

IN10

0V IN11

IN12

IN13

0VIN14

IN15

0VIN16

IN8

IN7

IN6

IN5

IN4

IN3

IN20VIN1

Aux

(+) 1

2 VD

C

VBU

S

OP2

OP1

0V Tam

per

12 0V

12 VTB11 TB2

TB13

TB10TB9TB8

Module Bus(SNAPP)

Not usedTamperSpring

Rear tamper on back of board

P1 IN

Wire short to disable rear tamper

OP1 OP2LEDs

Power (green)

VBUS Active (yellow)

Processor OK (green)

Jumper to disable front tamper.

Not used

0V 0V 0V 0V 0V 0V

1 2 3 41 2 31 2 31 2 3 1 2 3 1 2 3

TB5 TB4 TB3

1 2 3

123 123 123 123 12

revision 1 — 57

16 Input Control Module NGP-1100

- End of line resistors 1k ohm, 1% (quantity = 32)- Machine screws (quantity = 4)- Tamper spring (quantity = 1)

11.2 Mounting the Module

Use the provided screws as required to mount the unit in one of the designated enclosures (the NGP enclosure, IPSU enclosure, LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies).

If you are mounting the module in a LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies determine the series of eight standoffs for mounting the module. Insert the module and mounting plate assembly, attaching it with the eight nuts provided.

Note: Do not overtighten the mounting screws.

Input control module mounting holes and dimensions

11.2.1 Anti-attack Bushing Cap

If this module is being mounted in the same enclosure as the intelligent power supply unit, an anti-attack bushing cap covers a rear tamper spring. It fits inside an O ring bushing located in the cabinet’s rear wall anti-tamper spring knockout. Leave the O ring bushing and cap in place if the rear tamper is not used.



TB12

TB7 TB1

TB6

12

TB11 TB2

TB13

TB10TB9TB8 P1 IN

OP1 OP2LEDs

1 2 3 41 2 31 2 31 2 3 1 2 3 1 2 3

TB5 TB4 TB3

1 2 3

123 123 123 123 12

5.375 in (136.53 mm)

5.75 in (146.05 mm)

2.43

75 in

(61.91

mm

)

2.812

5 in (71

.44 m

m)

0.1875 in (4.76 mm) 0.1875 in (4.76 mm)

0.1875 in (4.76 m

m)

0.1875 in (4.76 mm

)

58 — revision 1







11.3 VBUS

VBUS is an internal communication bus that related VBUS modules are used with. The VBUS is not intended for external use. It has been designed to be used in a protected enclosure with adjoining interconnection between modules in the same enclosure. VBUS devices must be located behind the tamper switch of its host device. Therefore, the wire length can never be greater than the size of the box. Three conductors are required.

11.4 Input Wiring

11.5 Power

Power for the input control module can be passed through the SNAPP connection.

Optionally, auxiliary power may be used to power the board. The 12 VDC auxiliary output (at TB13) supports up to 10 mA.

11.6 Status LEDs

• The Processor green LED will flash on and off for indication of normal CPU processing.

• The VBUS yellow LED will flash on and off if there is no VBUS board communicating on the VBUS. If a VBUS board is present, the VBUS LED will remain off.

• The Power green LED stays on providing the operating voltage remains above 9.5 V. If the voltage is lower, the LED will flash on and off.

• The two output LEDs follow when the outputs are active.

Typical Door Contact Circuit (Dual-EOL)

Door Contact InputCOM/Shared

Install resistors close to the contact

1kΩ1kΩ

revision 1 — 59

16 Input Control Module NGP-1100

11.6.1 Serial Number Display

When the board is initially powered, the serial number is displayed in an encoded form. The number of times the VBUS yellow LED flashes while the Processor OK green LED is on steady gives the digit value.

For example, if the green LED is on and the yellow LED flashes three times, then the green LED goes off, the first digit is “3.” Then if the green LED turns back on and the yellow LED flashes nine times, then the green LED goes off, the second digit is “9,” etc.

The entire serial number will be displayed, one digit at a time. It takes several seconds to complete the entire process.

“0” is indicated by the green LED turning on and the yellow LED not flashing. When the serial number display is complete, the Processor OK green LED will flash on and off at a more moderate rate.

11.7 Final Steps

1. Apply power to the unit and listen for the relays to click, verifying LED indicators for correct board operation.

2. When finished, ensure all wires are clear and secure of the cover before closing.

11.8 Specifications

The NGP-1100 is for use in low voltage, Class 2 circuits only. These specifications are subject to change without notice.

• Ratings

- Input: 12 VDC, 100 mA- Output: 12 VDC, 2x10 mA

• Inputs: Sixteen (16) inputs, standard EOL: 1k ohm in series, 1k ohm in parallel

• Outputs

- Two (2) relay outputs

• Communication: SNAPP, VBUS

• Cable requirements: 22 AWG, stranded

- SNAPP bus: four conductors- VBUS: three conductors- Input wiring: two conductors- Power input: two conductors

• Mechanical

- Dimensions: 5.75 x 2.875 x 0.6 in. (146 x 73 x 15 mm)

• Environmental

- Temperature: 0 to +49° C (32 to 120° F)- Humidity: 5 to 85% RHNC

• Certifications

- UL294 Listed- FCC Part 15- CE marking

60 — revision 1


12 8 Output Relay Control Module NGP-1208

The output expanders (model series 650-3641) are used to add additional output points to the system in groups of eight. Output points can be used to control such things as sirens, indicators, or other peripherals. The NGP intelligent system controller can be licensed to support a maximum of sixteen output relay control modules.

Output relay control module

The output relay expansion module must be connected to the NGP-1100 input control module. Up to four output relay expansion modules can be connected to any one input control module.

The NGP-1208 is available separately. It is also sold with a universal mounting plate (NGP-1216K-UMP). With the mounting plate, there are two boards, and it can be installed in either the LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies.

12.1 Packing List

• 8 output relay expansion module (quantity = 1)


- Three positional terminal plug-in block (quantity = 9)- Machine screws (quantity = 4)

TB5TB2 TB4TB3TB1

31 2

(+)12VDC IN

0V

VBUS 31

2

TB6 TB7 TB8

TB9

P5P4P3P2

NC

CO

MNO

Processor OK LED(with VBUS = slow flash,No VBUS = quick flash)

Not used - do not jumper

Relay LEDs (on when relays activated)

31 2 31 2 31 2 31 2 31 2 31 2 31 2

NC

CO

MNO NC

CO

MNO NC

CO

MNO NC

CO

MNO NC

CO

MNO NC

CO

MNO NC

CO

MNO

0.1875 in (4.76 mm)5.375 in (136.53 mm)

5.75 in (146.05 mm)0.1875 in (4.76 mm)

0.1875 in (4.76 m

m)

1.75 in (44.45 mm

)

2.125 in (53.95 mm

)0.1875 in (4.76 m

m)

revision 1 — 61

8 Output Relay Control Module NGP-1208


Use the provided screws as required to mount the unit in one of the designated enclosures (the NGP enclosure, IPSU enclosure, LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies).

If you are mounting the module in a LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies, determine the series of eight standoffs for mounting the module. Insert the module and mounting plate assembly, attaching it with the eight nuts provided.


12.3 Output Relay Expansion Module

• Each of the eight relay output connections can be Normally Closed or Normally Open.

• VBUS devices must be located behind the tamper switch of its host device per the UL standard. Therefore the wire length can never be greater than the size of the box. Three conductors are required so it is recommend to use the same cable as the SNAPP bus (22 AWG stranded).

• Communication to the NGP controller is through the VBUS connection via the input control module.

• Power is supplied to the output relay control module from the input control module.

• The unjumpered connector on the module is for factory use only. Do not jumper this connector.

12.4 Jumpers

Each output relay control module must have unique address. Use jumpers P2 and P3 to set the address.

Jumper P4 is not used — do not connect.

To perform a test on the output module, insert the P5 test jumper and remove the VBUS connection only. Within a minute, the relay LEDs should be activated. After testing, remove the P5 jumper and reconnect the VBUS.

VBUS Unit Address Jumper P2 Jumper P3

1 out out

2 IN out

3 out IN

4 IN IN

62 — revision 1


12.5 Status LEDs

• The relay LEDs turn on when the relays are activated. Use the P5 test jumper to turn the relay LEDs on or off.

• The Processor OK LED will flash slowly (about 0.5 second on and 0.5 second off) with VBUS and flash quickly (about 0.2 second on and 0.2 second off) without a VBUS connection.

12.6 Final Steps

1. Ensure the jumpers are configured correctly.



12.7 Specifications


• Power ratings

- Input: 12 VDC, 155 mA

• Outputs: 1 relay = 1 A resistive, 0.1 A inductive

• Communication: to NGP-1100 via VBUS

• Cable requirements: 22 AWG, stranded

• Mechanical


• Environmental

- Temperature: 0 to +49° C (32 to 120° F)- Humidity: 5 to 85% RHNC

• Certifications:

- UL294 Listed- FCC part 15- CE marking- RoHS compliant

revision 1 — 63

Dual Door Interface Module NGP-1320

13 Dual Door Interface Module NGP-1320

The dual door interface module (model series 950-901x) is capable of supporting two complete door configurations, with up to two readers per door. This dual door interface module provides termination points for door contacts (door position switches) and request to exit devices as well as two door strike relays to control power to the controlled access doors. It communicates to the NGP family of controllers via a 2-wire RS-485 bus. The NGP-1320 is to be used for access control only installations.

The NGP-1320 is available separately. It is also sold with a universal mounting plate (NGP-1320-UMP). With the mounting plate, it can be installed in either the LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies.

Dual door interface module

DOOR 2(1 or 2 Readers)

1 2 1 2 3

TB8 TB10

1 2 3

TB9

1 2 3 4GND RTMP BUZ 5/12 GRN RED/

RXDGNDDCNTRTEGNDAUXNO2COM2 R1D1 R1D0 R2D1NC2COM1NO1 R2D0

MODULE BUS

0V B A

MODULE BUS

(-) 0

V -B

lack

Da

ta B

- Y

ello

w

Da

ta A

- G

reen

(+)

12V

- R

ed

From Previous Device (and To Next Device)

TAMPER

Ground 0V - Black +5V

+5V

+12V

+12V

READER INPUT AUX RELAY

UNLOCK RELAY

INPUT READERUNLOCK RELAY

AUX RELAY

DOOR 2 READER

VOLTAGE

DOOR 1 READER VOLTAGE

NONC

R1

Dat

a 1

R1

Dat

a 0

Re

d LE

D

Gre

en L

ED

(+) 5

/12

VDC

BUZ

Out

(-)

Rea

der T

ampe

r

Doo

r Con

tact

Inpu

t

Req

uest

to E

xit (

RTE

)

Aux

Inpu

t

Com

mon

(Nor

mal

ly O

pen)

UNLOCKRELAY

(-) 0

V Si

gnal

Gro

und

C

OM

/Sha

red

FOR SERVICE KEYPAD

Aux

Rel

ay

DOOR 1(1 or 2 Readers)

1 2 3 4 5 6 1 2

C

OM

/Sha

red

R2

Dat

a 1

R2

Dat

a 0

1234+12V

TB1

5/12GRNRED/RXD

GND R1D1R1D0R2D1R2D0

R1

Dat

a 1

R1

Dat

a 0

Re

d LE

D

Gre

en L

ED

(+) 5

/12

VDC

(-) 0

V Si

gnal

Gro

und

12345612

R2

Dat

a 1

R2

Dat

a 0

TB2

1234GNDRTMPBUZ

BUZ

Out

(-)

Rea

der T

ampe

r

Doo

r Con

tact

Inpu

t

CO

M/S

hare

d

DCNT

TB3

123RTE GND AUX

Req

uest

to E

xit (

RTE

)

Aux

Inpu

t

CO

M/S

hare

d

12123NO2 COM2 NC2 COM1 NO1

NO

NC

Com

mon

(Nor

mal

ly O

pen)UNLOCK

RELAY

Aux

Rel

ay

TB5

TB6

0VB

A1

23

4+12V (+) 12V - Red

Data B - Yellow

Data A - Green

64 — revision 1


13.1 Packing List

• Dual door interface module (quantity = 1)


- Two positional terminal plug-in block (quantity = 5)- Three positional terminal plug-in block (quantity = 4)- Four positional terminal plug-in block (quantity = 4)- Six positional terminal plug-in block (quantity = 2)- 1N4005 diodes (quantity = 2)- End of line resistors 1k ohm, 1% (quantity = 8)- Plastic board supports for optional mounting (quantity = 1)


Use the provided screws as required to mount the unit in one of the designated enclosures (the NGP enclosure, LNL-CTX, LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies).

If you are mounting the module in a LNL-CTX or LNL-CTX-6 enclosure, AL400ULX or LNL-AL600ULX-4CB6 power supplies, determine the series of eight standoffs for mounting the module. Insert the module and mounting plate assembly, attaching it with the eight nuts provided.


revision 1 — 65


Dual door interface module mounting holes and dimensions

13.2.1 Anti-attack Bushing Cap

If this module is being mounted in the same enclosure as the controller or intelligent power supply unit, an anti-attack bushing cap covers a rear tamper spring. It fits inside an O ring bushing located in the cabinet’s rear wall anti-tamper spring knockout. Leave the O ring bushing and cap in place if the rear tamper is not used.








1 2 1 2 3

TB8 TB10

1 2 3

TB9

1 2 3 4GND RTMP BUZ 5/12 GRN RED/

RXDGNDDCNTRTEGNDAUXNO2COM2 R1D1 R1D0 R2D1NC2COM1NO1 R2D0

0V B A

TAMPER

Ground 0V - Black +5V

+5V

+12V

+12V

1 2 3 4 5 6 1 2

1234

+12V

TB1

5/12GRNRED/RXD

GND R1D1R1D0R2D1R2D0

12345612

TB2

1234

GNDRTMPBUZ DCNT

TB3

123RTE GND AUX

12123

NO2 COM2 NC2 COM1 NO1

TB5

TB6

0VB

A1

23

4+12V (+) 12V - Red

Data B - Yellow

Data A - Green

5.375 in (136.53 mm)3.875 in (98.42 m

m)

5.75 in (146.05 mm)0.1875 in

(4.76 mm)0.1875 in (4.76 mm)

4.25 in (107.95 mm

)0.1875 in

(4.76 mm

)0.1875 in (4.76 m

m)

66 — revision 1


13.3 Wiring

Door Unlock Circuit: A diode is provided to protect against voltages induced when a DC strike is de-energized. For an AC strike, or a magnetic-lock with reversing coils (or if unsure), you must use a 27 V Metal Oxide Varistor (MOV).

Verify that at least 10.5 volts are at each device (with relays energized). Use additional power supplies as necessary.

For large current-draw devices with built-in power supplies, connect the incoming and outgoing module bus +12 lines together, but do not connect to the +12 in the cabinet.

Components and cable specifications

Lock

To panel, or prev. MOD

RTE

*

Next 'MOD'

Last 'MOD'

22 AWG, shielded, 3 pairs

22 AWG, 1 pair

22 AWG, 1 pair

18 AWG, 1 pair

22 AWG, 1 pair

12 VDC Input power

Power Supply XFMR

Door1 or 2

Dual Door Controller

Module

22 AWG, 1 pairAux

Reader cable

RTE Button

Door Lock

Aux Relay

Aux Input

(with door-

closer)

Door Contact/Sensor

Module Bus22 AWG, 4 wires

shielded, 120 ohms

revision 1 — 67


13.3.1 Output Wiring

The contact protection circuit must be used. The following two circuits are recommended. Locate the protection circuit as close to the load as possible (within 12 inches [30cm]), as the effectiveness of the circuit will decrease if it is located further away.

12 VDC

+ -

1 (NC)

2 (C)

3 (NO)

DIODE CURRENT RATING > 1X STRIKE CURRENTDIODE BREAK DOWN VOLTAGE > 4X STRIKE VOLTAGEFOR 12 OR 24 VDC STRIKE, DIODE 1N4002 (100V/1A) TYPICAL

-

+

DC STRIKE

ACXFMR

1 (NC)

2 (C)

3 (NO)

CLAMP VOLTAGE > 1.5 X VAC RMSFOR 24 VAC STRIKE, PANASONIC ERZ-CO7DK470 TYPICAL

AC STRIKE

68 — revision 1


13.3.2 Reader Wiring

For the second reader of each door, the reader connections are shared (except for the Data 0 and Data 1 which are separate for each reader).

13.4 Jumpers

Reader power for Door 1 [J1] and Door 2 [J2]:

• 5V = 12V reduced to 5V at door

• 12V = 12V passed through to reader

13.5 Status LEDs

• LED 1: This is the Processor OK LED. Its normal action is a slow flash (about 1 second on, 1 second off).

• LED 2: This is the SNAPP OK LED. If the module serial number is configured and communicating with the main panel then the LED is on. If the module serial number is not programmed or not communicating the LED is off.

• LED 3: This is the Power BAD LED. If there is insufficient voltage or current then this LED will flash. If the voltage is normal then the LED is off.Magnetic Locks and other “Fail-Safe” Door Locks

The default door lock wiring is for “Fail Secure” (powered = unlocked). For magnetic-locks and other “Fail-Safe” door locks (powered = locked), move the NO wire to NC terminal for the specific unlock relay.

1 2 3 4 5 6 1 2TB11

5/12 GRNRED/RXD GNDR1D1 R1D0 R2D1 R2D0

READER

R2

DA

TA

0

R

2 D

AT

A 1

R1

DA

TA

1

R1

DA

TA

0

R

ED

LE

D

GR

EE

N L

ED

(+)

5/1

2 V

DC

(-)

0V S

IGN

AL

GN

D

RED (1)

BRN (4)

ORG (5)

WHT (3)

GRN (2)

BLK (6)

0 1

2 3

4 5

6 7

8 9

* #

revision 1 — 69


Note: The system shall not be installed in the fail secure mode unless permitted by the local authority having jurisdiction and shall not interfere with the operation of panic hardware. (Not evaluated by UL.)

13.6 Door Contact Detail and Request to Exit

13.7 Final Steps

1. Ensure the reader voltage jumpers match your specific readers.



13.8 Specifications


• Incoming power ratings: 12 VDC, 300 mA max

• Outputs

- Four outputs: Relay type- Door strike: 24 VDC/1 A- Aux: 24 VDC/0.1 A

• Inputs

- Eight (8) unsupervised/supervised, standard EOL, 1k/1k ohm, 1% 1/4 watt- One (1) unsupervised, dedicated for cabinet tamper

• Reader interface

- Four interfaces

X

1 NC2 Com3 NO

Typical Door Contact Circuit (Dual-EOL)

Door Contact InputCOM/Shared

Install resistors close to the door contact

Door Contact(must match /

follow the door state)1kΩ

1kΩ

70 — revision 1


- Reader power (jumper selectable): 12 VDC + 10% regulated, 125 mA maximum each reader or 5 VDC + 10% regulated, 600 mA maximum each reader

• Communication: SNAPP bus

• Cable requirements

- Power: 18 AWG, 1 stranded- Reader data: 6 conductors, 18 AWG, 500 feet (150 m) maximum- SNAPP bus (RS-485): 22 AWG, 100 ohm impedance, twisted pair with shield, 4000 feet (1219 m)

maximum

• Mechanical

- Dimensions: 5.75 x 4.25 x 1 in. (146 x 108 x 25 mm)

• Environmental

- Temperature: 0 to +49° C (32 to 120° F)- Humidity: 5 to 85% RHNC at 25° C (77° F)

• Certifications

- CE marking- RoHS compliant- WEEE

revision 1 — 71

NGP Intelligent Power Supply 120-3650/120-3651

14 NGP Intelligent Power Supply 120-3650/120-3651

The intelligent power supply unit (IPSU) communicates with the NGP main controller on its module communication bus (SNAPP), allowing remote diagnostics of the power supply. The power supply is rated to provide 13.8 VDC, 650 mA to peripheral devices on the system and will support a 12 VDC backup battery up to 17 Ahr. The power supply unit can feature a 230 VAC to 16 VAC transformer inside the enclosure for European requirements. Not evaluated by UL.

Intelligent power supply unit

*1 SNAPP Isolate: Jumper/short with wire to enable module bus (SNAPP) connector 12 VDC.

**2 Brownout Button: After installation and all power connections are complete, press this button to establish a frame of reference to detect a brownout.

NOC

NC

0V

12

TB

1

12

TB

2

31

24

TB

5T

B6

16.5 VAC/40 VA AC Mains16.5 VAC/40 VA AC Mains

Earth GNDEarth GND

Auxiliary (+)12VDC 0V

Auxiliary (+)12VDC

0V

(+)12V

(-) 0VData B

Data A Module Bus (SNAPP)

VBUS

TB

7

0V

TB

3T

B4

Battery Connectors

1.0

A O

utpu

t

(+)(-)Manual Battery Restart–momentarily jumper after a battery has been connected and there is no AC mains available.

Battery resettable fuse

Auxiliary powerresettable fuse

Cover Tamper Spring

Rear tamper

Not used - do not jumper.

Not used - do not jumper.

Factory set. Do not adjust.

1 2

*1SNAPP Isolate

Batteryplug

(+)12V

Not used

P3 jumper in = rear tamper bypassed

**2Button

Wire short for cover tamper spring operation only.

AC Mains ongreen LED

Additional CoverTamper Input

Pow

er O

nG

reen

LED

Trou

ble

Yello

wLE

DM

odul

e bu

s co

mm

unic

atio

n re

d LE

D

Processor OK green LEDslow flash. Fast flash with no VBUS connected.

(-)

(+)

P4P5P6P7P8P9P10

31

24

31

23

12

12

72 — revision 1


The maximum number of devices that can be mounted in the enclosure with the intelligent power supply unit is one NGP-1100 and up to three NGP-1208 modules.

Module power supply applications

Note: VBUS is an internal communication bus that related VBUS modules are used with. The VBUS is not intended for external use. It has been designed to be used in a protected enclosure with adjoining interconnection between modules in the same enclosure.

The following intelligent power supply units are available:

• 120-3650L - North American intelligent power supply without transformer

• 120-3651L - European intelligent power supply with external transformer

• 120-3658L - North American intelligent power supply with external transformer

14.1 Packing List

• Intelligent power supply unit in its enclosure (quantity = 1)


- Two positional terminal plug-in block (quantity = 4)- Three positional terminal plug-in block (quantity = 2)- Four positional terminal plug-in block (quantity = 2)

Main Control

Unit

Module Power Supply Module Power Supply Module Power Supply

VBUSVBUS VBUSSNAPP

Master Unit communicating to the main control unit on the module bus. The serial number is programmed. - P4 and P5 in- P9 and P10 ignored

Unit #1 on master unit VBUS. The serial number is ignored.

- P4 in, P5 out- P9 and P10 out = Address 0 or Unit #1

Unit #2 on master unit VBUS. The serial number is ignored.

- P4 in, P5 out- P9 out, P10 in = Address 1 or Unit #2

- Parallel connections- 0V and VBUS- 12VDC connection not needed

Mod

ule

bus

(SN

AP

P)

VBUS VBUS

revision 1 — 73


- End of line resistors 1k ohm, 1% (quantity = 2)- Machine screws with lock washers (quantity = 4)- Machine screws (quantity = 4)- Tamper spring (quantity = 1)- Battery cable (quantity =1)- Cable tie (quantity = 1)- Cable tie mounting pad (quantity = 1)- Replacement anti-attack bushing cap (quantity = 1)


Use the provided screws as required to mount the unit in the IPSU enclosure.


IPSU mounting holes and dimensions

12

TB

1

12

TB

2

31

24

TB

5T

B6

Module Bus (SNAPP)

TB

7

TB

3T

B4

(+)(-)

1 2

P4P5P6P7P8P9P10

31

24

31

23

12

12

3.875 in (98.42 mm)

4.25 in (107.95 mm)

5.375 in (136.53 mm

)

5.75 in (146.05 mm

)

0.1875 in(4.76 mm)

0.1875 in (4.76 mm)

0.1875 in(4.76 m

m)

0.1875 in (4.76 mm

)

74 — revision 1


IPSU enclosure

The enclosure can accommodate one input control module and up to three output relay expansion module as field upgrades.

Intelligent Power Supply Unit

11.875 in (301.62 mm)

18.3

75 in (466.72 m

m)

9.72 in (247 mm)

14.41 in (366 mm

)

0.984 in (25 mm) 0.984 in (25 mm)

1.4375 in (36.51 mm

)1.9375 in (49.21 m

m)

revision 1 — 75


14.2.1 Anti-Attack Bushing Cap

An anti-attack bushing cap covers a rear tamper spring. It fits inside an O ring bushing located in the cabinet’s rear wall anti-tamper spring knockout. Leave the O ring bushing and cap in place if the rear tamper is not used.








14.3 Jumpers

Jumpers P4, P5, P6, P7, and P8 are used to configure power supply type and other selections.

Power supply type and other selections P4 P5 P6 P7 P8

Module bus (SNAPP) and VBUS master (P9 and P10 are ignored.)

IN IN

VBUS (Set P9 and P10 VBUS Address.) IN out

Module bus (SNAPP) ONLY out IN

Stand-alone, no module bus or VBUS out out

110V operation IN

220V operation out

Relay test - disconnect the module bus (SNAPP). Momentarily insert P7 jumper and remove again. Relay will cycle on, off for 10 seconds.

out

Defeat battery - where a standby battery is not required, insert P8 jumper and the system will ignore battery monitoring.

out

76 — revision 1


Important: Jumper P8 must be left out for battery monitoring.

Jumpers P9 and P10 are used to configure addressing.

14.4 Status LEDs

• AC Mains On (green) - on with electrical present

• Power on (green) - on if auxiliary DC power is present

• Trouble (yellow) Normal = not on. This LED will flash on and off for:

- AC Mains failure- Battery loss- Module Bus (SNAPP) not active (turns on solid if one or more of the board tampers are active)

• Processor OK

- Normally will flash on and off slowly- Flashes on and off rapidly when VBUS is present

Relay Trouble Output - changes state with any trouble mentioned above.

14.5 Power Supply LCD Keypad Diagnostics

• The power supply must be communicating with the main control module.

• A user with the authority to view status can view these screens locally or using the OnGuard software.

• Critical conditions can be reported through keypad alert and communications, and Alarm Monitoring.

• For local annunciation, the following steps are required:

- In the Status menu, using the left and right keypad arrow keys, select Power and press the keypad button below Ok.

- Use the left and right arrow keys to select the status of Overall system power condition or the main Panel or the power supply, IPSU.

- Selecting Overall will display that the system’s power conditions are either in Trouble or Ok.- When finished viewing or entering items, you can use the [x] key to back out of keypad screens you

are viewing and return to previous ones or go to others.- Select Panel and press Ok. This will supply left/right arrow key selections for the condition of the

panel's AC mains, DC (main control module auxiliary power) or the battery connected to the main controller (e.g. select AC and press Ok).

- If an end user has logged on to view these screens, they will see if the AC mains for the main panel is Ok, is in Failure or has had a Brownout condition (AC voltage too low).

Power supply VBUS address

P9 P10

1 out out

2 out IN

3 IN out

4 IN IN

revision 1 — 77


14.6 Main Panel and Power Supply AC Condition Calibration

If a service user has logged on and views these screens, they can press [3] and see Cal for calibration. The keypad button beneath Cal can be pressed to calibrate the AC condition. This is a tool to attempt to correct a problem. An additional screen will not display. If this clears the problem, Ok will appear.

14.7 Voltage and Current Conditions

• Any user logged on can select DC or the battery conditions of the main panel using SNAPP bus.

• Auxiliary DC conditions that may display are: Relay Cutoff, Fuse Failure, Low Voltage, Overload.

• Battery conditions are: No Battery, Cutoff, Shorted, Wrn Cutoff, Low, Exces Curr (excessive current), Discharge, Charge.

• If the button below VC is pressed for either a Main Panel DC or standby battery condition, the related voltage and current will display.

14.8 Power Supply Displays

• AC mains, Auxiliary DC and Battery conditions can be displayed for a power supply module.

• Because the power supply can be configured with the previously explained jumpers into different types of units, the same will display for the power supply module.

Example 1:

- The AC mains connection of the IPSU01 (intelligent power supply unit or power supply module #1) is an M01 (module bus (SNAPP) unit only) and is in Failure condition.

- AC mains conditions that can display are: Failure, Brownout, Offline.

Example 2:

- The auxiliary DC of the IPSU01 (intelligent power supply unit or power supply module #1) is a M01V1 (module bus (SNAPP) VBUS master unit) and VBUS unit #1 on its VBUS is experiencing low voltage. The button below VC can be pressed to view the condition’s voltage and current.

- DC conditions that can display are: Relay Cutoff, Fuse Failure, Low Voltage, Overload.

Example 3:

- The battery connection of the IPSU01 (intelligent power supply unit or power supply #1) is V1 (VBUS unit #1 connected to the main control unit) and is low.

- Battery conditions that can display are: No Battery, Cutoff (battery disconnect by unit), Shorted, Wrn Cutoff (warning cutoff), Low, Exces Curr (excessive current), Discharge, Charge (battery charging), Offline (battery disconnected). The button below VC can be pressed to view the unit’s voltage and current.

14.9 Specifications

These specifications are subject to change without notice.

78 — revision 1


• Ratings

- North America (part number 120-3650):

– Input: 16.5 VAC/40 VA/50-60 Hz/60 W, 50 mA

– Output: 12 VDC- Europe (part number 120-3651):

– Input: 230 VAC/50 Hz, 50 mA

– Output: 12 VDC

• Communication: SNAPP bus

• Board dimensions: 5.75 x 4.25 in. (146.05 x 107.95 mm)

• Cabinet dimensions: 11.875 x 18.375 x 3.375 in. (301.62 x 466.72 x 85.72 mm)

• Environmental

- Temperature: 0 to +49° C (32 to 120° F)- Humidity: 5 to 85% RHNC at 25° C (77° F)

• Certifications

- FCC part 15- CE marking- RoHS

revision 1 — 79

Worldwide Modem 120-3633L

15 Worldwide Modem 120-3633L

The worldwide modem is available for reporting alarms and system events to monitoring stations. The modem should be housed in an enclosure and plugged directly into the NGP intelligent system controller. The worldwide modem is for use with controllers with the intrusion feature.

Notes: Use minimum 26 AWG UL/CSA or equivalent approved telephone cable.

Not evaluated by UL.

15.1 Worldwide Modem with 8 output STU

• Designed to meet the telecom requirements worldwide

• 2400 baud

• It can automatically dial when required and also seize the telephone line if it is busy at the time.

• For output programming with an NGP LCD keypad, refer to the NGP LCD Keypad Programming Reference Guide.

Worldwide modem

31

24

Seized TipSeized Ring

TipRing

Off Hook LED

Connect to NGP

7 5680V Li

ne F

ailu

re

9 3 124

Out

put 8

Out

put 7

Out

put 6

Out

put 5

Out

put 4

Out

put 3

Out

put 2

Out

put 1

To Central Station Receiver

01

123

CPU Failure

From Central Station Receiver

80 — revision 1


Worldwide modem when using Redcare

15.2 Packing List

• Worldwide modem (quantity = 1)


- Three positional terminal plug-in block (quantity = 2)- Four positional terminal plug-in block (quantity = 2)- Machine screws (quantity = 4)


Open the cover. Plug the modem into the main panel. Then use the supplied screws to mount the unit.


15.4 Status LEDs

There is one LED indicator on the worldwide modem board. The LED indicates that the phone line is in use (off hook indication).

31

24

Seized TipSeized Ring

TipRing

Off Hook LED

Connect to NGP

7 568

0V Line

Fai

lure

9 3 124

Out

put

8O

utp

ut 7

Out

put

6O

utp

ut 5

Out

put

4O

utp

ut 3

Out

put

2O

utp

ut 1

To Central Station Receiver

From REDCARE Unit

01

Not UsedLeave defaulted

revision 1 — 81


15.5 CPU Failure

Output 8 must be programmed as “System Fault” in System Outputs. For a negative to positive output, it can be left defaulted. For a positive to negative output, it must also be programmed to be inverted.

The jumpers on the modem are used for monitoring CPU failure.

• Place two vertical jumpers in 1 and 2 to have Output 8 be 12 VDC high from 0V if the main control board CPU fails.

• Place two vertical jumpers in 2 and 3 to have Output 8 be 0V low from 12 VDC high if the main control board CPU fails.

• Place one vertical jumper in 1 and 2 on the left side to have Output 8 be a standard output #8 on this board.

Jumpers in position 1 and 2

15.6 Enable Line Failure

This feature is used to monitor for line faults from switched communicators such as Redcare.

The worldwide modem must be plugged into the main control module.

Advanced Configurations: S005 03

• Field 2: Parallel STU 8OP Supports Line Fail:

(yes) (no) Default: no (UK ACPO = yes)

• Field 3: Parallel STU 8OP Line Fail Negative Polarity:

(yes) (no) Default: no = Positive Polarity STU (subscriber terminal unit)

Enable Equipment failure point E16 (HSC, Security IP, Trouble). Set delay as 01 immediate in Advanced programming. If the worldwide modem has a Line Failure condition, it will be indicated by an HSC fault.

15.7 Specifications

The worldwide modem is for use in low voltage, Class 2 circuits only. These specifications are subject to change without notice.

Notes: Pulse dialing is not supported in Australia.

The worldwide modem has not been evaluated by UL.

123

82 — revision 1


• Ratings

- Input: 12 VDC, 145 mA- Output: 12 VDC, 8x10 mA

• Mechanical


• Environmental

- Temperatures: 0 to +49° C (32 to 120° F) - Humidity: 5 to 85% RHNC

• Certifications

- FCC part 15- CE marking

revision 1 — 83


84 — revision 1


Index

Numerics

16 input control module ...................................... 578 output relay control module ............................. 61

A

AC inductive loads.............................................. 17AC power .............................................................. 9Alarms

supervised ...................................................... 9unsupervised .................................................. 9

Anti-attack bushing cap ........................ 58, 66, 76

B

Belden wires ....................................................... 11

C

Cable termination................................................ 12Capacities............................................................ 36CPU failure ......................................................... 82Current overload ................................................. 14

D

DC inductive load ............................................... 17DC negative ........................................................ 16DC power .............................................................. 9Device configuration checks............................... 19Device placement................................................ 14Device to device connection ............................... 12Dual door interface module

anti-attack bushing cap ................................ 66jumpers ........................................................ 69mounting ...................................................... 65output ........................................................... 68packing list................................................... 65reader ........................................................... 69specifications ............................................... 70status LEDs.................................................. 69wiring........................................................... 67

E

Enable line failure ............................................... 82

F

Firmware updates................................................ 21

G

Ground potential difference checks .................... 19

Ground wiring..................................................... 15Grounding system............................................... 16

I

Input .................................................................... 59Input control module

anti-attack bushing cap ................................ 58input wiring.................................................. 59mounting...................................................... 58packing list................................................... 57power ........................................................... 59serial number display................................... 60specifications ............................................... 60status LEDs.................................................. 59vbus.............................................................. 59

Inputs .................................................................... 9Installation .......................................................... 38Intelligent power supply

anti-attack bushing cap ................................ 76jumpers ........................................................ 76mounting...................................................... 74packing list................................................... 73specifications ............................................... 78status LEDs.................................................. 77

Interface signals .................................................... 9Interfaces............................................................. 35

K

Keypad wiring..................................................... 41

L

LCD keypad diagnostics ..................................... 77

M

Modem ................................................................ 80

N

NGP board .......................................................... 36NGP board LEDs ................................................ 49NGP intelligent power supply............................. 72NGP-1100 ........................................................... 57NGP-1208 ........................................................... 61NGP-1320 ........................................................... 64

O

Open collector output.......................................... 10Output relay control module

jumpers ........................................................ 62

revision 1 — 85

Index

mounting ...................................................... 62packing list................................................... 61specifications ............................................... 63status LEDs.................................................. 63

Outputs.................................................................. 9Overview............................................................. 35

P

Power .................................................................. 43AC.................................................................. 9DC.................................................................. 9UL................................................................ 23

Power requirements ............................................ 14

R

Reader data input ................................................ 10Reader wiring...................................................... 40Redcare ............................................................... 81Relay contact protection ..................................... 17Relay outputs ...................................................... 10Replace battery ................................................... 51RS-485

cable............................................................. 12communication ............................................ 10wiring........................................................... 17

S

Safety ground...................................................... 16SOM board LEDs ............................................... 49Specifications...................................................... 52Status................................................................... 49Supervised alarms ................................................. 9System capacities ................................................ 36System turn-up considerations............................ 19System wiring

considerations .............................................. 14current overload ........................................... 14device placement ......................................... 14power requirements ..................................... 14

U

ULcertified installations.................................... 22power ........................................................... 23

Unsupervised alarms............................................. 9

V

VBUS.................................................................. 59

W

Wiring ................................................................. 38Worldwide modem ............................................. 80

86 — revision 1


revision 1 — 87

Lenel Systems International, Inc.1212 Pittsford-Victor RoadPittsford, New York 14534 USATel 585.248.9720 Fax [email protected]

NGP Hardware Installation Guide

Documents

Transcript of NGP Hardware Installation Guide