Product Catalogue - VECTOR 751 Optical FTTB ... Network throughput comparable to EPON/GPON ... Increased RF spectrum in both downstream and upstream > ? - ˛% @

Product CatalogueNetwork Infrastructure Solutions

300employees

750000annual production

capacity

25 years in the industry

VECTOR is an international,

technology company

Designs and manufactures

solutions for telecommunications

operators

A manufacturing facility in Europe

Active access network equipment & digital television

headends

More than 60 R&D engineers

��

warehouse in one place

45countries

presencety

vector.net 1

Content 1

Business cases 2

VECTOR product categories 6

�� 7

VECTOR Optical Nodes 7

BOOSTRAL Optical Nodes 8

BOOSTRAL 7910 Segmentable optical node 2x4, 2 active outputs, 1.2 GHz / 200 MHz 10

BOOSTRAL 7810 Segmentable optical node 2x2, 2 active outputs, 1.2 GHz / 200 MHz 11

BOOSTRAL 7710 Optical node 1x2, 2 active outputs, 1.2 GHz / 200 MHz 12

BOOSTRAL 6610 Optical node 1x1H, 1 active output, 1 GHz / 200 MHz 13

BETA PRO 60 G Optical node, 1x2, 1 GHz / 85 MHz 14

GAMMA O33 Optical node, 3 active outputs, 862 MHz / 65 MHz 15

RFoG Optical Nodes 16

BOOSTRAL 751 Optical FTTB micronode, 1 active output, 1.2 GHz / 200 MHz 17

BOOSTRAL 651 Optical node RFoG MDU, 1 active output, 1 GHz / 200 MHz 18

BOOSTRAL 611 Optical RFoG SDU FTTH micronode, 1 active output, 1 GHz / 85 MHz 19

Optical Receivers 20

OPTIMER 4510 Optical receiver for 100 HP, 1 active output, 1 GHz 21

LAMBDA PRO 71/72 Optical receiver for 100 HP, 1 active output, 862 GHz 22

LAMBDA PRO 70 Optical receiver for 100 HP, 1 active output, 862 GHz 23

OPTI Optical receiver for 10 HP, 1 active output, 862 MHz 24

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HARGON 3810 �� !�� 27

HARGON 3710 �� !�� 28

HARGON 3610 �� !�� 29

HARGON 351 "��#��!�� 30

ContentProduct catalogue

HARGON 2730 $�� !�� 31

HARGON 2710 $�� !�� 32

HARGON 2630 $�� !�� 33

HARGON 2610 $�� !�� 34

HARGON 261 $�� !�� 35

GAMMA PRO 40 �� 36

GAMMA U33 $�� 37

BETA PRO 30 $�� 38

BETA PRO 20/21 $�� 39

�� 40

HARGON 2410 %��!�� 40

LAMBDA PRO 20 %�� 41

AMIGO A %�� 42

AMIGO P %�� 43

VECTOR Accessories for devices 44

VECTOR INGRESS GUARD Ingress Detection System 45

ALSCAutomatic Level and Slope Control Module 46

DCM/EDCM T DOCSIS/EURODOCSIS Communication Module 47

DCM/EDCM DOCSIS/EURODOCSIS Communication Module 48

HCM HMS Communication Module 49

VALUE MAX TRANSPONDER HMS Communication Module 50

CMS Craft Management Software 51

BHHT Basic Hand Held Terminal 52

Scheme of 1.2 GHz Plug-in Modules 53

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Plug-in modules 55

Cont

ent

vector.net 2

REGIONALHEADEND

REGIONALHEADEND

REGIONALHEADEND

MAINHEADEND

HARGON 3710/3610

BOOSTRAL 7910

HARGON 3710/3610

HARGON 351

HARGON 351

HFC Network UpgradeEffective solutions for extending network capacity

Increasing customer requirements, the implementation of new services and technologies and strong market competition all lead to the fact that broadband service providers are challenged to expand the capacity of their Hybrid Fiber-Coax (HFC) networks.

�&'��(��)�� )��*(��*��)�� +��)��-��7��7��-��9��:�# ��(�� (�� )�� ;��*��+�*��)�� )��-��(�*��&'��+��*��-��and competitiveness in the face of the increasing demands of subscribers.

While traditional HFC networks work with e.g. a 862MHz bandwidth, the extension up to 1GHz or 1,2 GHz provides an increase of the total bandwidth which can be split for both Upstream and Downstream. The extension of the bandwidth enables operators to offer a wider range of services.

The most popular scenario implemented by many cable operators to increase the available bandwidth per subscriber is node splitting and deeper network segmentation in order to share the available bandwidth between a smaller number of customers connected to the same optical node cluster.

HFC network

Busin

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Business CaseHFC Network Upgrade

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Advantages of Fiber Deep solutions:

Maximizing the return on investment in HFC technology < ��-��%��-��=Higher network capacity – smaller segments <��+�� -��'��=Network throughput comparable to EPON/GPONLower energy consumption compared to standard HFCHigher reliability due to the limited number of devices in cascadeLower OPEX costs owing to the limited number of devices, ��*�� of devices in the network

REGIONALHEADEND

REGIONALHEADEND

REGIONALHEADEND

MAINHEADEND

FTTH

FTTB

ARCHITECTURE N+0

ARCHITECTURE N+1

BOOSTRAL 751

BOOSTRAL 6610HARGON 2410

HARGON 2410

BOOSTRAL 6610

BOOSTRAL 751BHHT

Busin

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Fiber Deep NetworksFuture proof scenarios for high speed broadband access

The natural evolution of traditional HFC networks, caused by the growing demand for high-speed broadband access, � ��'�" �! �*�+��#�� %��#��"�� :� ��+ �" �;+��+� �� #�+ ��:��"�� ;��<��"��+ �" �� + ��"��" �*=�; ��+ ��" ��#��"��" ��;+��+�� +� �� " � ��"� �� ## �� ;�� "��;��+�� *

Fiber Deep Network

Business CaseFiber Deep Networks

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%��(��*�� )��-��Services with improved noise performanceIncreased RF spectrum in both downstream and upstream>��?��-��%��@��RFoG continues to use existing CPE <$J'>9>�'!��>�?=�

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RFoG MDU

RFoG SDU

RFoG – RF over Glassa transition technology to FTTH

RF over Glass (RFoG) is a technique used in the access network using the same RF/DOCSIS technology as traditional HFC systems. The coax part of the network is replaced by the Passive Optical network (PON). The signals can be �� ">�" ��"��" �� #?@<�*�� + !��JKJ��"��+on the subscriber’s side and headend equipment, are supported by RFoG and can operate further. It allows for future smooth migration to Next Gen xPON.

RFoG OBI FREE solution

Business CaseRFoG - RF over Glass

Busin

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vector.net 5

TVDATA

VOICE

MAINHEADEND

MAINHEADEND

Tx 1550nm

TV HEADENTANALOG / DVB-T / DVB-C

GPON OLT

EDFA

SPLITTER SWITCH

WDFM COMBINER

GPON ONT

DATAVIDEO

DATAVIDEO

DATA ETHVIDEO

REGIONALHEADEND

IPCMS

DATAVOICE

LAMBDA PRO 71

LAMBDA PRO 70

OPTI

LAMBDA PRO 72

1550nm

1310nm

1490nm

An additional, large bandwidth for analogue and digital signals that does not affect the data transmission bandwidth�*)�@��(��-��*��*��*��K�� @��@��-��)�� *�� <��>�?��=The system operates based on open standards, such as DVB and PALExcellent scalability, simplicity of the design, construction and development of the system and adding optical receivers, services and users

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Business CaseRF Video Overlay for FTTH networks

RF Video Overlayfor FTTH networks

RF Video Overlay is a solution for telecommunications operators who apply xPON technology or Ethernet P2P to insert television services (analogue TV/FM signal and digital television) over an extra parallel bandwidth without reducing the present capacity. While not using any subscriber’s devices e.g. STB, the Video Overlay reduces CAPEX spending. Two separate parallel systems enable the operator to deliver more services thus increasing his offer and competitiveness.

RF Video Overlay

vector.net 6

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VECTOR products Naming structure

Select type and series of BOOSTRAL optical node

Type

V SERIES Q SERIES

Segmentable optical node 2x42 active outputs, 1.2 GHz/ 200 MHz

BOOSTRAL 7900

Segmentable optical node 2x2 2 active outputs, 1.2 GHz/ 200 MHz

BOOSTRAL 7800

Optical node 1x22 active outputs, 1.2 GHz / 200 MHz

BOOSTRAL 7700

Optical node 1x1 high gain 1 active output, 1 GHz/ 200 MHz

BOOSTRAL 6600

Optical FTTB micronode 1 active output, 1.2 GHz/ 200 MHz

BOOSTRAL 750

Optical RFoG SDU FTTH micronode 1 active output, 1 GHz/ 85 MHz

BOOSTRAL 610

Select type and series of OPTIMER receiver

Optical receiver for 100 HP 1 active output, 1 GHz

OPTIMER 4500

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��<Q��"�� 3 active outputs, 1.2 GHz / 200 MHz

HARGON 3800

��<Q��"�� 2 active outputs, 1.2 GHz / 200 MHz

HARGON 3700

��<Q��"�� 1 active output, 1.2 GHz / 200 MHz

HARGON 3600

=�� :� �� 1 active output, 1.2 GHz/ 200 MHz

HARGON 350

�� 1 active output, 1 GHz/ 200 MHz

HARGON 2400

PRODUCT LINE

CLASS - PLACE IN NETWORK

7 - 1.2 GHz6 - 1 GHz

MODEL - FOLOWING

NUMBER

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FUNCIONALITY FOR VARIETY

OF NEEDS

BOOSTRAL 7 9 1 0

PRODUCT LINE

CLASS - PLACE IN NETWORK

3 - 1.2 GHz2 - 1 GHz

MODEL - FOLOWING

NUMBER

HARGON 3 5 1

vector.net 8

Response to your variety of needs

Exactly what you need

V SERIES Q SERIES

BOOSTRAL 7910Segmentable optical node 2x4

2 active outputs, 1.2 GHz/ 200 MHz

BOOSTRAL 7810Segmentable optical node 2x2

2 active outputs, 1.2 GHz/ 200 MHz

BOOSTRAL 7710Optical node 1x2

2 active outputs, 1.2 GHz / 200 MHz

BOOSTRAL 751Optical FTTB micronode

1 active output, 1.2 GHz / 200 MHz

BOOSTRAL 611Optical RFoG SDU FTTH micronode

1 active output, 1 GHz / 85 MHz

New

BOOS

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Pro

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If you are looking for modern optical node, which is ready for future challenges, the BOOSTRAL V

series is the answer to your needs.

If you are looking for reliable optical node, which will meet your expectations, and you do not want

to pay for unnecessary features, the BOOSTRAL Q series is exactly what you are looking for.

New BOOSTRAL ProductsV SERIES / Q SERIES

vector.net 9

BOOSTRAL 7910 First 1.2 GHz

optical node 2x4 on the market!

vector.net 10

1. In range 85 - 600 MHz; ± 0.75 dB in range 600-1006 MHz; ± 1.0 dB in range 1006 - 1218 MHz2.��(��`��)��+��^��j��q��3. According to EN 50083-3, 9 dB slope between 85 to 862 MHz, 42 channels CENELEC, typ. value4. Full digital load 258 - 1218 MHz, 120 channels QAM 256, 12 dB slope5. AGC on, 3.25% OMI, - 7 dBm optical input level, 1310 nm6. Unbalanced split with splitter / tap out7. Up to 85 MHz; ± 0.75 dB up to 204 MHz 8. For CWDM lasers, up to 16 wavelengths are available9.�}�)�j��j�~�j�_�j�^��?��*��-��>��*��10.�!��+�)��?��<�_�� =��^��!��?}��%9K'��j��q��11. In 5 - 65 MHz; 18 dB for f < 40 MHz; 18 dB -1.5 dB / oct for f > 40 MHz, but > 11 dB12.�_��j'`�'��*��#�&}$��#��~#��?��'}$!��%$'!�

��)��+��)��+)��+�)�^_�]_��#��`� at room temperature 25°C and present typical values.

1.2 GHz technologyAn extended bandwidth in downstream up to 1.2 GHz; DOCSIS 3.1 standard compliant

GaN TechnologyThe Output parameters for analog and digital carriers improved for lower power consumption

200 MHz technology A possibility of extending bandwidth in upstream up to 200 MHz; DOCSIS 3.1 standard compliant

Forward ParametersWavelength 1260 – 1620 nmBandwidth 85…258 – 1218 MHzOptical input power range - 9.9 – 2 dBmOptical AGC range - 7 – 0 dBmFlatness 1 ± 0.5 dB%@��2 _��j��q��Output level 3��'�?��7�^��?� '>J��7^�?��

2 x 116 dBμV2 x 116 dBμV

Digital Output level 4

CINR = 41.5 dB 2 x 109 dBμV

Gain limited output level 5 2 x 118 dBμVNumber of outputs 6 2 active, up to 4 with passive splitting

Return Parameters Bandwidth 5 – 65…204 MHz Flatness 7 ± 0.5 dBOptical output power 8 3 ± 0.5 dBMin RF input level to get 10% OMI 9 70 dBμVNPR / Dynamic range 10 40 dB / 5 dB

Others Return loss 11 > 18 dB j'��*��*�� remote powering 30 – 65 V AC

Max. current for RF / AC IN ports 10 / 15 A Power consumption 12 < 45 W Operation temperature range 13 - 40 – 60 °C Optical connectors SC/APC RF connectors 4x PG11 Protection class IP 67 $��<}�#�"�#��=� 255 x 234 x 128 mmWeight < 4.0 kg

Available Versions BOOSTRAL 7910 489Y ��+��*`��#��*��x x 4Tx

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BOOSTRAL 7910 Segmentable optical node 2x4


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Digital Output level 4CINR = 41.5 dB 2 x 109 dBμV


Return Parameters Bandwidth 5 – 65…204 MHz Flatness 7 ± 0.5 dBOptical output power 8 3 or 6 dBm ± 0.5 dBMin RF input level to get 10% OMI 9 70 dBμVNPR / Dynamic range 10 40 dB / 5 dB


Max. current for RF / AC IN ports 10 / 15 A Power consumption 12 < 41 W Operation temperature range 11 - 40 – 60 °C Optical connectors SC/APC RF connectors 3x PG11 Protection class IP 67 $��<}�#�"�#��=� 255 x 234 x 128 mm Weight < 4 kg


1. In range 85 - 600 MHz; ± 0.75 dB in range 600-1006 MHz; ± 1.0 dB in range 1006 - 1218 MHz2.��(��`��)��+��^��j��q��3. According to EN 50083-3, 9 dB slope between 85 to 862 MHz, 42 channels CENELEC, typ. value4. Full digital load 258 - 1218 MHz, 120 channels QAM 256, 12 dB slope5. AGC on, 3.25% OMI, - 7 dBm optical input level, 1310 nm6. Unbalanced split with splitter / tap out7. Up to 85 MHz; ± 0.75 dB up to 204 MHz 8. For CWDM lasers, up to 16 wavelengths are available in 3 dBm version and 8 wavelengths are available in 6 dB version9.�}�)�j��j�~��j�_��j�^��?��*��-��>��*��10.�!��+�)��?��<�_�� =��^�!��?}��%9K'��j��q��11. In 5 - 65 MHz; 18 dB for f < 40 Mhz; 18 dB -1.5 dB / oct for f > 40 MHz, but > 11 dB12.�_��j'`�'��*��#�&}$��#��#��?��'}$!��%$'!�

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HF

VIG

!�;�� [9��*��*��<j��j��=�� 0 - 20, step 0.5 dB9��*��<%��%��=�� 0 - 20, step 0.5 dBJ��<?�*��=��<%��%�~=�� 0 - 20, step 1.0 dB\�� [9��*��<j��j�~��j�_��j�^=�� 0 - 20, step 0.5 dB9�*��+��)��7^��7��?

BOOSTRAL 7810 Segmentable optical node 2x2


Optic

al No

des

vector.net 12






Return Parameters Bandwidth 5 – 65 … 204 MHz Flatness 7 ± 0.5 dBOptical output power 8 3 or 6 dBm ± 0.5 dBMin RF input level to get 10% OMI 9 70 dBμVNPR / Dynamic range 10 40 dB / 5 dB


Max. current for RF / AC IN ports 10 / 15 A Power consumption 12 < 40 W Operation temperature range 13 - 40 – 60 °C Optical connectors SC / APC RF connectors 3 x PG11 Protection class IP 67 $��<}�#�"�#��=� 245 x 234 x 130 mmWeight < 5 kg


1. In range 85 - 600 MHz; ± 0.75 dB in range 600-1006 MHz; ± 1.0 dB in range 1006 - 1218 MHz2.��(��`��)��+��^��j��q��3. According to EN 50083-3, 9 dB slope between 85 to 862 MHz, 42 channels CENELEC, typ. value4. Full digital load 258 - 1218 MHz, 120 channels QAM 256, 12 dB slope5. AGC on, 3.25% OMI, - 7 dBm optical input level, 1310 nm6. Unbalanced split with splitter / tap out7. Up to 85 MHz; ± 0.75 dB up to 204 MHz 8. For CWDM lasers, up to 16 wavelengths are available in 3 dBm version and 8 wavelengths are available in 6 dB version9.�}�)�j��j�~��j�_��j�^��?��*��-��>��*��10.�!��+�)��?��<�_�� =��^��!��?}��%9K'��j��q��11. In 5 - 65 MHz; 18 dB for f < 40 Mhz; 18 dB -1.5 dB / oct for f > 40 MHz, but > 11 dB12.�_��j'`�'��*��#�&}$��#��#��?��'}$!��%$'!�

��)��+��)��+)��+�)�^_�]_��#��`��_�'��present typical values.




Electronic controlj�@��*��`��)��*��-��)��*7in modules not needed anymore

�&�Y��&�"�� Z'��7-��(��*��)��*)��





LED Indicator%��(��*�� (��*� ��"%$�9��

OPTICAL FWD RX 1

NMS TRANSPONDER

LED INDICATOR

IS

IS


OE


Control buttons

NMSREV

AC IN

SMPS

DF

DF

OPT. IN

AT1

AT2

EQ1

EQ2

AT4

AT5

VIG / NMSFWD

OPT. OUT

DF

EQ3

SP/TO/JP

IS

OE

AGC

LF/BF

OE

LF/BF

AT3

TP -20dB

LF/BF

HF

HF

REV TX 1

REV TX 2

TP -20dB

VIG

!�;�� [9��*��*��<j��j��=�� 0 - 20, step 0.5 dB9��*��<%��%��=�� 0 - 20, step 0.5 dBJ��<?�*��=��<%��%�~=��0 - 20, step 1.0 dB\�� [9��*��<j��j�~��j�_��j�^=�� 0 - 20, step 0.5 dB9�*��+��)��7^��7��?

Optic

al No

des

BOOSTRAL 7710 Optical node 2x4


vector.net 13

1.��-��+�� -��2. Range of AGC3.��_�j��q��(��4. 4.0% OMI/channel, single carrier; input wavelength 1310 nm, AGC = ON5.�!��!�� #��7�--��+�)�j��6. According to EN 50083-3, 9 dB slope between 85 to 862 MHz, 42 channels CENELEC, value measured & guaranteed per each product7. Noise bandwidth=4.75 MHz, input optical power = - 3 dBm, 112 dBμV output level, AGC = OFF, A1 = A2 = E1 = 08.�>�� +��~��!�� )��@��9.�&��^_�?��<�_�_�?��=��9>��J&&��?10. f >15 MHz, room temperature11.��]�?�-��!��-��~��!��]�?�7��_�?��-��-��~��!�� ?12. Sinus 30V AC, without plug-in modules; with transmitter and NMS transponder < 26 W, Intelligent Power Consumption mode with transmitter < 16 W13.�J�)��@��14.�$��+�)�+��*�)�*��^�#��#��15. >�� +��~��!)�� )��@��

��)��+��)��+)��+�)�� ^_�]_�!��`��%%K��`��_�'�

Optical ParametersWavelength 1 1100 – 1600 nmOptical input power range 2 - 8 – 2 dBm%@��3 ��_��j��q��

RF Parameters

Forward ChannelForward bandwidth _~��^��^��Gain limited output level 4 119 ± 1 dBμVFlatness 5 ± 0.75 dBSlope 5 ± 1 dB Output level 6�'�?��7�^��?� '>J��7^��?��

117 dBμV117 dBμV

CNR 7 51.5 dBc9��*��*��<j�= 0 – 20 step 0.5 dB9��*��<%�=�8 0 – 20 step 0.5 dB

Reverse ChannelBandwidth _��~��Transmitter OMI 9 10 %Flatness ± 1 dB��*��<j�= 0 – 24 step 1 dBHUM modulation @ 5A 10 < -60 dBc

Available VersionsBOOSTRAL 6610 289Y remote powering BOOSTRAL 6610 289M mains powering

Others Return loss 8 Z��]�?Test points - 20 ± 0.75 dBj'��*��*�� remote powering mains powering

30 – 65 V AC110 – 230 ± 10% V AC

Max. current for RF / AC IN ports 5 / 7 APower consumption 12 < 21 WOperation temperature range - 40 – 60 °COptical connectors 13 SC / APCNumber of RF ports / connectors types 2 / PG11Protection class IP 67$��<}�#�"�#��=�11 245 x 199 x 90 mmWeight 2.4 kg

1 GHz technologyAn extended bandwidth in downstream up to 1GHz


200 MHz technology A possibility of extending bandwidth in upstream up to 200MHz

FTTB (Fiber To The Building) designTo be used in a modern FTTB architecture

HHT (Hand Held Terminal) supportj�@��*��-��`��)��of the network



Low Noise Receiver'j�%�� (��*��)�� -��@��

LED Indicator%��(��*�� (��*� ��"%$�9��

CMS (Craft Management Software) compliant An easy and convenient network documentation thanks to CMS software

Optic

al No

des

BOOSTRAL 6610 Optical node 1x1H

1 GHz / 200 MHz

μP Controller

NMS Transponder

BHHT

LED DISPLAY

Control buttons

RBPL

LPBL

TP -20dB

TP -20dB

IS

AGC

optical receiver

CWDM

optional filter

A1 E1

A2

HHT port

LTOATG 0

PORT 2 PORT 1

4A

MAX 5A

MAX 5A

AC IN 7A

DC

SMPS

vector.net 14

1.��-��+�� -��2. Range of AGC3.��_�j��q��(��4.�~��J!9��)��*��+��?��+�*��7��?��)*)�*��`��wavelength 1310 nm, AGC = OFF5.�!��!�� #��7�--��+�)�j��6. According to EN 50083-3, 9 dB slope between 85 to 862 MHz , 42 channels CENELEC, value measured & guaranteed per each product7. Noise bandwidth=4.75 MHz, input optical power = - 3 dBm, 112 dBμV output level, AGC = OFF, A1 = A2 = E1 = 08.�>�� +��~��!�� )��@��9.�&��?��<�~�?��=��?��(10. f >15 MHz, room temperature, typical value11.��]�?�-��!��-��~��!��]�?�7��_�?��-��-��~��!�� ?12.�>��j'��*��}�)�-��*��-��K!>�transponder < 41 W13.�J�)��@��14.�$��+�)�)�*��-��*�� +�)��)�*��-��)��+��*��+�)�+��*�)�*��260x233x130 mm

��)��+��)��+)��+�)�^_�]_��#��_��'�

1 GHz in downstream / up to 100 MHz in upstream

2 active GaAs outputs, 3 ports

Fiber optic transmitters with OMI stabilization

Uninterruptable electronic adjustment

Optional Network Management Transponder (DOCSIS, EuroDOCSIS, HMS)

Forward path redundancy

Return path redundancy or segmentation

BETA PRO 60GOptical node

Optic

al No

des

Optical power based AGC

Build in optical input power level indicator

Easy set-up using LED display or BHHT terminal

Compact housing and protection class IP 67

CMS compliant

Optical ParametersWavelength 1 1100 – 1600 nmOptical input power range 2��*)�*��<��= "�+�*��<"�=

-8 – -1 dBm-5 – 2 dBm

%@��3 ��_��j��q��

Available VersionsBETA PRO 60G D89Y remote powering BETA PRO 60G D89M mains powering

Others Return loss 11 Z��]�?Test points - 20 ± 0.75 dB��*��*�� remote powering mains powering

35 – 65 V AC230 ± 10% V AC

Max. current for RF / AC IN ports 12 / 15 APower consumption 12 < 33 WOperation temperature range - 40 – 60 °COptical connectors 13 SC / APCNumber of RF ports / connectors types 3 / PG11Protection class IP 67$��<}�#�"�#��=�11 245 x 204 x 127 mmWeight 4 kg

RF Parameters

Forward ChannelForward bandwidth 54...130 – 1006 MHzGain limited output level 4 2 x 118 ± 1 dBμVFlatness 5 ± 0.75 dBSlope 5 ± 1 dB J��'�?��7�^��?��'>J��7^��?��6 114 dBμVCNR 7 51.5 dBc9��*��*��<j��j�= 0 – 15 step 0.5 dB9��*��<%�=�8 0 – 15 step 0.5 dB

Reverse ChannelBandwidth _��~��Transmitter OMI 9 8 %Flatness ± 1 dB��*��<j��j~= 0 – 24 step 1 dBHUM modulation @ 12A 10 < -60 dBc

A

IS1

NMS FWD

NMS REV

IS2

1

2

AT 1000TO 10XX

A / B SWITCH

B

LED DISPLAY

P Controller

RBP2

RBP1REVERSE PATH

BHHT

NMS Transponder

A10÷15dB

E10÷15dB

A20÷15dB

A40÷24dB

DF xxG

DF xxG

A30÷24dB

FTB

FTB

12A

12A

12A

CONFIGURATION UNIT

ATG

ATG

Control buttons

SMPS

vector.net 15

1. For input optical power = 0 dBm and 4.5% OMI/channel, 1310 nm, AGC = OFF2.�$��#��$&��;��j��]��j��]��3. According to EN 50083-3, 9 dB slope between 85 to 862 MHz , 42 channels CENELEC, typical value4. With RCG 015.�&��-��_��_�!��!��7�__�?��_�'��(��6.��]�?�-��!��-��~��!��]�?�7��_�?��-��-��~��!�� ?7. Except port 18.��j��7��J&��7�]��J��&��9. Port 1 - external input 5 – 210 MHz of ORT F1310 transmitter10.�$��+�)�+��*�)�*��^�#��#��

��)��+��)��+)��+�)�^_�]_��#��at room temperature 25°C.

Optical ParametersWavelength 1100 – 1600 nmOptical input power range - 5 – 2 dBm%@��(�� ]��j��q��

RF Parameters

Forward ChannelForward bandwidth 85 – 862 MHzRF level at the output of the OFR 1 78 ± 1.5 dBμVMax. output level 1 3 x 117 ± 2 dBμVFlatness 2 ± 1 dBSlope 2 ± 1 dB Output level 3�'�?��7�^��?� '>J��7^��?��

110 dBμV110 dBμV

Reverse ChannelBandwidth 5 – 65 MHzGain 4 21 ± 0.75 dBHUM modulation @ 12A 5 ��7�^_�?�

Available VersionsGAMMA O8X-33A-AF8 remote powering GAMMA O8M-33A-AF8 mains powering

Others Return loss 6 Z��]�?Test points - 20 ± 1 dB��*��*�� remote powering mains powering

35 – 65 V AC230 ± 10% V AC

Max. current for RF / AC IN ports 7 12 / 15 APower consumption 8 42 WOperation temperature range - 40 – 60 °COptical connectors SC / APCNumber of RF ports / connectors types 9 4 / PG11Protection class IP 67$��<}�#�"�#��=�10 245 x 204 x 130 mmWeight 4.2 kg

3 active GaAs outputs

Forward path redundancy

Reverse path redundancy or segmentation

Optional Network Management Transponder (HMS)

Automatic Gain Control unit (AGC)

Current passing capability up to 12A

Additional 15A power inserter

IP 67 compact housing

4 3

11

3

22

4

5

4 3

2

15

4 3

2

15

4 3

2

1 5 5 5

4 4 43 3 3

2 2 2

1 1 15

2

1

TP2

4

REVERSECONFIGURATION

MODULE*

3

125

4 3

2

1

O

O

E

E

TP3 TP4

O

E

HPG

OSR-870 (option)OFR-870

optical input 2(option)

optical input 1

CSC/AP

EQ1 ATG

AGC(option)

ATGATGATG

EQ2 EQ3 EQ4NMS2CONNECTOR

RF IN

RF OUT

opticaloutput 1

opticaloutput 2

SC/APCORT

ORT(option)

REVERSEAMPLIFILTER

MODULE**

RAG 29-1

RHP2

RHP1

TP7

TP6

TP5

ISG 2

ISG 3

ISG 4

AUTOLINK

AUTOLINK

AUTOLINK

ATG

ATG

ATG

DF

DF

DF

DC Voltage

PSGSMPS

AC IN 12A

12A

12A -20dB -20dB -20dB

PORT3 PORT4PORT2

RAG 29-1

**REVERSE AMPLIFIER MODULES *REVERSE CONFIGURATION MODULES

RAG-29-2 RJP

RCG-01

RCG-01 RCG-02 RCG-03 RCG-04 RCG-05 RCG-06 RCG-07

Optic

al No

des

GAMMA O33 Optical node

vector.net 16

vector.net 17

1. In a range 85 - 862 MHz; ± 1.5 dB up to 1218 MHz; typical value2. According to EN 50083-3; 12 dB slope between 85 - 862 MHz; 42 channels CENELEC; typical value3. Full digital load 258 - 1218 MHz, 120 channels QAM 256, 12 dB slope 4. AGC ON; 3.5% OMI; -6 dBm optical input level; 1550 nm; typical value5. Up to 204 MHz; typical value6. With attenuation AT 2 = 5dB7. European RFoG IEC 60728-14 standard compliant8.�!��+�)��?��<�_�� =��^��!��?}��%9K'��j��q��9. In 5 - 65 MHz; 18 dB for f < 40 MHz; 18 dB - 1.5 dB/oct for f > 40 MHz, but >11 dB10. Parameters are guaranteed in typical temperature range - 20 - 55 °C


Optical ParametersWavelength 1550 ± 6.5 nmBandwidth 85…258 – 1218 MHzOptical AGC range - 6 – 0 dBmFlatness 1 ± 1.0 dB%@��9��K��'�� ^��j��q��Output level @862 MHz 2��'�?��7�_]�?� '>J��7�_��?��

112 dBμV112 dBμV


CINR = 41.5 dB 103 dBμVGain limited output level 4 113 dBμV

Return ParametersWavelengths up to 8 Number of channels per wavelength up to 4&��@��(��*� 12 – 65…204 MHzFlatness 5 ± 1.0 dBJ��+��ONOFF

3 ± 0.5 dBm< - 30 dBm

RF input threshold 6 75 ± 2 dBμVLaser rise/fall time 7 < 1 / < 1 μsMin RF input level to get 14% OMI 6 75 dBμVNPR / Dynamic range 8 40 dB / 5 dB

Others Return loss 9 Z��]�?�Directional testpoints FWD /REV -20 ± 0.75 dB / - 10 ± 0.75 dB��*��*�� +��*�<�j'�9K��=mains powering

30 – 65 V AC230 ± 10% V AC

Max. Current for RF / AC IN ports 1 / 1 A Power consumption < 14 W Operation temperature range - 40 – 65 °COptical connectors SC / APC RF connectors 1 x F femaleProtection class IP 65$��<}�#�"�#��=� 218 x 204 x 87 mmWeight 1.5 kg

Available Versions BOOSTRAL 751 259M O ��+��*�� BOOSTRAL 751 259E O ��+��*�� BOOSTRAL 751 259M P ��+��*��#�JK��@��BOOSTRAL 751 259E P ��+��*��#�JK��@��


BURST modej��-��*��(��#��`��`��*(��

200 MHz technology A possibility of extending bandwidth in upstream up to 200 MHz; DOCSIS 3.1 standard complian

RFoG MDU/FTTB To be used in a modern RFoG MDU/Fiber To The Building architecture

OBI FREE SYSTEMDevice designed to work in OBI FREE system

VIG (VECTOR INGRESS GUARD) system compliant (on request)��-��)��-��*��)��+��

xPON port (on request)j�:�# �� )�� with xPON networks

reverse transmitter

IS

OUT1

CWDM

FILT

ERS

xPON

OPT. IN/OUT

On request

OPT. IN/OUT

VIG

On request

LF

optical receiver

AC IN

!�;�� [9��*��*��<j��=��7��?��?�<��=9��*��<%��=��7��~�?��\�� [9��*��<j��=��7��?��?�<��=

RFoG

Opt

ical N

odes

BOOSTRAL 751Optical FTTB micronode


vector.net 18

1. ,25% OMI/channel; one carrier; Pin = -8 dBm; wavelength 1310 nm; AGC = ON;2. ± 1 dB up to 862 MHz; ± 1.5 dB up to 1 GHz3. Measured between 10 MHz above roll-off of DF and 1006 MHz; E1 = 0 dB4. With accordance to EN 50083-3, slope 12 dB from 40 MHz to 1 GHz; CENELEC 42; typ. value5. Noise BW = 4.75, Pin = -3 dBm, RF output level 110 dBμV; AGC = OFF, A1 = A2 = E1 = 06. With 5 dB reverse ATG7. REV Tx 1310 FP 0 dBm8.��]�?�-��!��-��~��!��]�?�7��_�?��-��-��~��!�� ?9. Sinus 30 VAC; with REV Tx and FWD Rx10.�J�)��@��11. Dimensions with hinges

��)��+��)��+)��+�)��)�� ^_�]_�!��`��_�'

1 GHz technologyAn extended bandwidth in downstream up to 1 GHz

200 MHz technology A possibility of extending bandwidth in upstream up to 200 MHz DOCSIS 3.1 standard complian

FTTB (Fiber To The Building)To be used in a modern FTTB architecture

RF Parameters

Forward ChannelBandwidth 85 / 110 / 260 – 1006 MHzGain limited output level 1 112 ± 1 dBμVFlatness 2 ± 1 dBSlope 3 ± 1 dB Output level @ 862 MHz 4�'�?��7�^��?� '>J��7^��?��

110 dBμV112 dBμV

CNR 5 51.5 dBc9��*��<j�= 0 – 20 dB9��*��@��<%�= 0 / 9 / 12 dB

Reverse ChannelBandwidth 5 – 65 / 85 / 200 MHzSlope ± 1 dB��<j�= 0 – 20 dB

Burst ModeRF input threshold 6 75 ± 0.5 dBμVOptical output power, RF > input threshold 7 3 ± 0.5 dBmOptical output power, RF < input threshold OFFLaser rise time / Laser fall time < 1 μs

Available Versions

BOOSTRAL 651 ��+��*�� +��*�� +��*��+�� +��*��+��

BOOSTRAL 651 259M P mains powering, xPONBOOSTRAL 651 259E P remote powering, xPON

Others Return loss 8 Z��]�?$��&}$�<�%�= 7��_�?�<7��_�?=��*��*�� remote powering mains powering

30 – 65 V AC230 ± 10% V AC

Power consumption 9 < 10.5 WOperation temperature range - 20 – 60 °COptical connectors 10 SC / APCConnectors 2 x FProtection class IP 42$��<}�#�"�#��=�11 156 x 126 x 74 mmWeight 1.5 kg


BURST modej��-��*��(��#��`��`��*(��


Low Noise Receiver'j�%�� (��*��)�� -��@��


BOOSTRAL 651Optical node RFoG MDU


Optical ParametersWavelength 1100 – 1600 nmOptical AGC range - 8 – 2 dBm%@�� _�_��j��q��

optical receiver

AGCA1

E1

ATG

IS DF

GREEN 1GREEN 0

ONOFF

CWDM filter

only in BL 651 O andBL 651 P version

CWDM filter

only in BL 651 P version

reverse transmitter

TP -10dB

AC IN

SMPS

TP -20dB PORT 1

RBP

RFoG

Opt

ical N

odes

vector.net 19

1. In range 85 - 862 MHz; ± 1.5 dB up to 1006 MHz; typical value2. In accordance to 3 dB slope from 85 MHz to 1 GHz; CENELEC 42; typical value3. 3,5 % OMI/channel; single carrier; Pin = - 6 dBm; wavelength 1550 nm4. J�)��@��5. Up to 85 MHz; typical value6. European RFoG IEC 60728-14 standard compliant 7.�!��+�)��?��<�_�� =��^�!��?}��%9K'��j��q��8. In 5 - 65 MHz; 18 dB for f < 40 MHz; 18 dB - 1.5 dB/oct for f > 40 MHz , but not worse than 11dB9. Powered via DC port; power supply consumes additional 1W


Forward ParametersWavelength 1543 – 1555nmBandwidth 85…105 – 1006 MHzOptical AGC range - 6 – 0 dBmFlatness 1 ± 2 dBEINC ��_��j��q��Output level @862 MHz 2��'�?��7�^��?� '>J��7^~�?��

80 dBμV80 dBμV

Gain limited output level 3 80 dBμV ± 2 dBμV

Return Parameters

Wavelengths 4 up to 8 &��@��(��*� 5 – 65…85 MHzFlatness 5 ± 1 dBJ��+��ONOFF

3 ± 0.5 dBm< - 30 dBm

RF input threshold 70 dBμV ± 2 dBμVLaser rise/fall time 6 < 1 / < 1 μsMin RF input level to get 3.5 % OMI 93 dBμVNPR / Dynamic range 7 40 dB / 5 dB

Others Return loss 8 Z��]�?

��*��*��+��* external power supply 230V AC / 12V DC connected to the PWR IN port

Power consumption 9 < 2.7 WOperation temperature range 0 – 40 °COptical connectors SC / APCRF connectors type 1 x F femaleProtection class IP 42$��<}�#�"�#��= 124 x 102 x 31 mmWeight 0.5 kg

Available Versions BOOSTRAL 611 256M O �#��+��(�� _��^_�!��BOOSTRAL 611 258M O �#��+��(�� _��]_�!��BOOSTRAL 611 256M P �#��+��(��#�JK��_��^_�!��@��BOOSTRAL 611 258M P �#��+��(��#�JK��_��]_�!��@��

1 GHz technologyExtended bandwidth in downstream up to 1GHz

OBI FREE SYSTEMDevice designed to work in OBI FREE system

BURST modej��-��*��(��#��`��`��*(��

RFoG SDU/FTTHTo be used in a modern RFoG SDU/Fiber To The Home architecture


OUT1

CWDM

FILT

ERS

xPON

On request

OPT. IN/OUT

OPT. IN/OUT

reverse transmitter

RFoG

Opt

ical N

odes

BOOSTRAL 611Optical RFoG SDU FTTH micronode


vector.net 20

OPTIMER 4510

NEW EFFICIENT OPTICAL RECEIVER

FOR VIDEO OVERLAY ARCHITECTURE

vector.net 21

1.��]�?�-��-��~��!��]�?�7��_�?��-��-��~��!��2. According to EN 50083-3, 9 dB interstage slope, 42 channels CENELEC, typical value3. 0 dBm / 4.5% OMI / ch. AGC = ON4. Including connectors

��)��+��)��+)��_��'

Optical ParametersWavelength 1100 – 1600 nm J��<j�'��*�= -7 – 0 dBm %@�� _�_��j��q��J��+��<*��= - 9.9 – 1.9 dBm

RF Parameters Bandwidth 47 – 1006 MHz Flatness ± 1 dBReturn Loss 1 Z�7��]�?�Output level 2��'�?��7^�?�� '>J��7_]?��

114 dBμV114 dBμV

Gain limited output level 3 114 dBμVInterstage slope control 0 / 6 / 9 dBInterstage gain control 0 – 20 step 1 dBTest point - directional - 20 ± 0.75 dB

Others Powering 230 ± 10% V AC Power consumption < 16 W Operation temperature range - 20 – 55 ºC Optical connector SC / APCRF connector &�<��)��@��=��Protection class IP 42 $��<}�#�"�#��=�4 157 x 136 x 69 mm Weight 0.8 kg

Available Versions OPTIMER 4510 050M mains powering


FTTB (Fiber To The Building)To be used in a modern FTTB architecture

Low Noise Receiver'j�%�� (��*��)�� -��)��@��

LED Indicator%��(��*�� (��*� ��"%$�9��

Optic

al Re

ceive

rs

OPTIMER 4510 Optical receiver for 100 HP

1 active output, 1 GHz

vector.net 22

1.��-��+�� -��2. Range of AGC3.��_�j�q��(��4. 4.0% OMI/channel, single carrier; input wavelength 1310nm, AGC=ON5.�!��!�� #��7�--��+�)�j��6. According to EN 50083-3, 9dB slope between 85 to 862MHz , 42 channels CENELEC, value measured & guaranteedper each product7. Noise bandwidth=4.75MHz, input optical power=-3dBm, 112dBμV output level, AGC=OFF, A1=A2=E1=08. >�� +��~�!�� )��@��9.�&��^_?��<�_�_?��=��9>�J&&��?10. f >15MHz, room temperature11.��]?�-��!��-��~�!��]?�7��_?��-��-��~�!�� ?12. Sinus 30V AC, without plug-in modules; with transmitter and NMS transponder < 26W, Intelligent Power Consumption mode with transmitter < 16W13. J�)��@��14.�$��+�)�+��*�)�*��^�#��#��

��)��+��+�)�� ^_�]_!��`��%%K��`��_�'

Ability to operate at low optical power levels

One or two inputs version

Built-in optical AGC

SNMP monitoring

WEB Interface

Electronic management

Digital indication of input optical power level

A high RF output level over the entire range of AGC

Optical ParametersWavelength 1100 – 1600 nm Optical input power range - 7 – 0 dBm %@�� _��j��q��Optical power consumption - 9.9 – 1.9 dBm

RF Parameters Bandwidth ~��]^��Flatness ± 1 dB Return Loss 1 ��]�?Output level 2��'�?��7^�?�� '>J��7^�?��

Z��~�?��Z��~�?��

!�#��<~�_��J!9��j�'�JK= Z��~�?��Interstage slope control 0 / 6 / 9 dBInterstage gain control 0 – 20 dBTest point - 20 ± 0.75 dB

Others Powering 230 ± 10% V ACPower consumption < 11 W Operation temperature range - 20 – 55 ºC Optical connector SC / APCRF connector FMonitoring system connector ��~_�Monitoring system interface Ethernet 10/100 Mbps Protection class IP 42 $��<}�#�"�#��=�14 157 x 136 x 69 mm Weight 0.8 kg

Available Versions LAMBDA PRO 71 D50M without redundant optical receiver LAMBDA PRO 72 D50M with redundant optical receiver

Control parametersread write

Optical input power Rx A / Rx B 3 - 9.9 – 1.9 RReceivers working mode 3 A, B, redundancy R WAGC working mode ON / OFF R WAttenuator value 0 – 20 dB R WAlarm signals „Alarm” open / close ROutput level dBμV RTemperature ºC RVoltage V R

LAMBDA PRO 71/72 Optical receiver for 100 HP

1 active output, 1 GHz

Alarm 1

AGCA

0 0dB÷2

flat

Alarm 2

slope 6dB

E1slope 9dB

RF PORT 1TP -20dB

Optical receiver A

Optical receiver B

Only in LAMBDA PRO 72

μP Controller

Only in LAMBDA PRO 72

LED DISPLAY

Control buttons

IP NETWORK ETHERNETCOMMUNICATIONS

MODULE

Optic

al Re

ceive

rs

vector.net 23

Optic

al Re

ceive

rs

1.��]�?�-��-��~��!��]�?�7��_�?��-��-��~��!��2. According to EN 50083-3, 9 dB interstage slope, 42 channels CENELEC, typical value3. 0 dBm / 4.5% OMI / ch. AGC = ON4. Including connectors

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Optical ParametersWavelength 1100 – 1600 nm J��<j�'��*�= - 7 – 0 dBm %@�� _��j��q��J��+��<*��= - 9.9 – 1.9 dBm

RF Parameters Bandwidth 47 – 862 MHz Flatness ± 1 dBReturn Loss 1 Z��]�?�Output level 2��'�?��7�^��?�� '>J��7�^��?��

114 dBμV114 dBμV

Gain limited output level 3 114 dBμVInterstage slope control 0 / 6 / 9 dBInterstage gain control 0 – 20 step 1 dBTest point - directional - 20 ± 0.75 dB

Others Powering 230 ± 10% V AC Power consumption < 10 W Operation temperature range - 20 – 55 ºC Optical connector SC / APC RF connector &�<��)��@��=�Protection class IP 42 $��<}�#�"�#��=�4 157 x 136 x 69 mm Weight 0.8 kg

Available Versions LAMBDA PRO 72 D50M mains powering

Optical AGC

Digital indication of input optical power level

Ability to operate at low optical power levels

High power output

No additional plug-ins required

Local powering 230V AC

Low power consumption

LAMBDA PRO 70 Optical receiver

AGC

flatslope 6dB

RF PORT 1TP -20dB

μP Controller

LED DISPLAY

A0-20dB

Eslope 9dB

Control buttons

SC / APC

vector.net 24

1.��~�?�-��-��~��!��~�?�7��_�?��-��-��~��!��2. According to EN 50083-3, 6 dB interstage slope, 42 channels CENELEC, typical value3. - 3 dBm / 4.5% OMI / ch.4. Including connectors

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Optical ParametersWavelength 1100 – 1600 nm J��<j�'��*�= - 7 – 0 dBm %@��(�� ^��j��q��

RF Parameters Bandwidth 47 – 862 MHz Slope < 6 dBFlatness ± 1 dBReturn Loss 1 Z��~�?�Output level 2��'�?��7^�?�� '>J��7^�?��

101 dBμV101 dBμV

Gain limited output level 3 102 dBμV

Others Powering 230 ± 10% V AC Power consumption < 6 W Operation temperature range - 20 – 50 ºC RF connector F Optical connector SC / APC Protection class IP 40 $��<}�#�"�#��=�4 120 x 107 x 52 mm Weight 0.65 kg

Available Versions OPTI F50M ��#��*7�OPTI V50M 1 output, variable adjustment

Full bandwidth cable television 47 – 862MHz delivery

Wide optical input range

Local power supply

Easy maintenance

High reliability and stability

Compact design

Optic

al Re

ceive

rsOPTI 50

Optical receiver for 10 HP1 active output, 862 MHz

SC/APCO

E

AT10-18dB

ORATG

PORT 1

vector.net 25

NEW 1,2 GHz AMPLIFIERS

HARGON 3810 / HARGON 3710 / HARGON 3610 / HARGON 351

HARGON AMPLIFIERS ARE EXACTLY WHAT

YOU NEED

vector.net 26

HARGON 351 �"��[��<��%'*"��

1 active output,1.2 GHz / 200 MHz

HARGON 3810 ��$��\�<"#��" $�"��%'*"��

3 active outputs,1.2 GHz / 200 MHz

HARGON 3710 ��$��\<"#��" $�"��%'*"��


HARGON 3610 ��$��\�<"#��" $�"��%'*"��


Response to your variety of needs

Exactly what you need

V SERIES Q SERIES

]��J�$��*��"�>��%�<��<"#��" $�"��%'*"��which is ready for future challenges, the HARGON V


]��J�$��*��"�>��%�<��<"#��" $�"��%'*"��which is ready for future challenges, the HARGON Q


New

HARG

ON P

rodu

cts

New HARGON ProductsV SERIES / Q SERIES

vector.net 27

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1. According to EN50083-3, 9 dB interstage slope between 85 - 862MHz, 42 channels CENELEC2. Full digital load 258 - 1218 MHz, 120 channels QAM 256, 12 dB slope3.�K�� 7��?¡��_�7��~�!��+�)��]��!��*��_�?��*��4. For f >15 MHz, per port5.��]�?�-��-��~��!��]�?��7��_�?��-��-��~��!�� +��)��?6. For 65 V AC

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RF Parameters

Forward ChannelBandwidth 85...258 – 1218 MHzGain @ 1.2 GHz trunk/ distribution 3 x 34 / 44 ± 0.75 dBK��*�� < 7.5 dBFlatness trunk/ distribution ± 0.5 / ± 0.75 dBOutput level 1�'�?��7�^��?� '>J��7�^��?��




9��< 7��= - 20 ± 1 dBJ��<��= - 20 ± 0.75 dB

Reverse ChannelBandwidth 5 – 65...204 MHzGain @ 204 MHz 3 x 25 ± 0.75 dBK��*�� < 7.5 dBFlatness ± 0.5 dBNPR / Dynamic range 3 50 dB / 20 dB

Available VersionsHARGON 3810 079Y remote powering

Others ��*��*��+��* 30 – 65 V ACMax. current for RF ports / AC IN ports 10 / 15 AHUM modulation 4 ��7�^_�?��-��jReturn loss 5 > 18 dBPower consumption 6 46 WOperation temperature range - 40 – 60 °CRF Connectors 4 x 5/8”Protection class IP 67ESD protection 4 kVSurge protection 6 kV$��<}�#�"�#��=� 255 x 234 x 128 mmWeight 4 kg




Electronic controlj�@��*��`��)��*�� of the plug-in modules not needed anymore

ALSC (Automatic Level and Slope Control) Flat and stable Output characteristics due to the compensation of temperature changes in the cables


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AC IN

SMPS

DF

AT 2 EQ 3

TP -20dB

INPUT

TP -20dB TP -20dB

DF

DF

AT 3 EQ 4

AT 4 EQ 5

JP/HFJP/SEQEQ 2AT 1JP/CS/EQ1

EQ 7 AT 8 JP/SEQ/EQ 6

AT 5IS 1JP/LF/BF

IS 2

IS 3

AT 6

AT 7

DF

EC

TP -20dB

EC / ALSC / VIG /VIG + ALSC

JP/LF/BF

JP/LF/BF


HARGON 3810 ��$��\�<"#��" $�"��%'*"��


!�;�� [9��9��*��*��<j��j��j��j~=�0 - 20, step 0.5dB9��9��*��<%��%��%��%�~=�� 0 - 18, step 1.0dB

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0 - 20, step 0.5dBJ��<%�~=��

0-18, step 0.5dB9�*��+��)��<9>��9>��9>�=��

0, -6, -40 dB

vector.net 28

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RF Parameters

Forward ChannelBandwidth 85...258 – 1218 MHzGain @1.2 GHz trunk / distribution 2 x 34 / 44 ± 0.75 dBK��*�� < 7.5 dBFlatness trunk / distribution ± 0.5 / ± 0.75 dBOutput level 1�'�?��7�^��?� '>J��7�^��?��




9��< 7��= - 20 ± 1 dBJ��<��= - 20 ± 0.75 dB

Reverse ChannelBandwidth 5 – 65...204 MHzGain @204 MHz 2 x 25 ± 0.75 dBK��*�� < 7.5 dBFlatness ± 0.5 dBNPR / Dynamic range 3 50 dB / 20 dB


Others ��*��*��+��* 30 – 65 V ACMax. current for RF ports / AC IN 10 / 15 AHUM modulation 4 ��7�^_�?��-��jReturn loss 5 > 18 dBPower consumption 6 36 WOperation temperature range - 40 – 60 °CRF Connectors 3 x 5/8”Protection class IP 67ESD protection 4 kVSurge protection 6 kV$��<}�#�"�#��=� 255 x 234 x 128 mmWeight 4 kg







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AC IN

SMPS

AT 2 EQ 3

TP -20dB

INPUT

TP -20dB TP -20dB

DF

DF

AT 3 EQ 4

JP/HFEQ 2AT 1JP/CS/EQ1

EQ 6 AT 6 JP/SEQ/EQ 5

AT 4IS 1JP/LF/BF

IS 2 AT 5

DF

EC

JP/SEQ


JP/LF/BF


HARGON 3710 ��$��\�<"#��" $�"��%'*"��


!�;�� [9��9��*��*��<j��j��j��j~=�0 - 20, step 0.5dB9��9��*��<%��%��%��%�~=��0 - 18, step 1.0dB

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0 - 20, step 0.5dBJ��<%�~=��

0-18, step 0.5dB9�*��+��)��<9>��9>��9>�=��

0, -6, -40 dB

vector.net 29

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RF Parameters

Forward ChannelBandwidth 85...258 – 1218 MHzGain @1.2 GHz trunk / distribution 34 / 44 ± 0.75 dBK��*�� < 7.5 dBFlatness trunk / distribution ± 0.5 / ± 0.75 dBOutput level 1�'�?��7�^��?� '>J��7^��?��

118 dBμV118 dBμV


CINR = 41.5 dB 110 dBμV

9��< 7��= - 20 ± 1.0 dBJ��<��= - 20 ± 0.75 dB

Reverse ChannelBandwidth 5 – 65...204 MHzGain @204 MHz 25 ± 0.75 dBK��*�� < 7.5 dBFlatness ± 0.5 dBNPR / Dynamic range 3 50 dB / 20 dB


Others ��*��*��+��* 30 – 65 V ACMax. current for RF ports / AC IN 10 / 15 AHUM modulation 4 ��7�^_�?��-��jReturn loss 5 > 18 dBPower consumption 6 21 WOperation temperature range - 40 – 60 °CRF Connectors 3 x 5/8”Protection class IP 67ESD protection 4 kVSurge protection 6 kV$��<}�#�"�#��=� 261 x 225 x 88 mmWeight 1.5 kg







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AC IN

SMPS

TP -20dB

INPUT

TP -20dB

DF

AT 2 EQ 3JP/HFJP/SEQEQ 2AT 1JP/CS/EQ1

EQ 5 AT 4 JP/SEQ/EQ 4 AT 3IS 1JP/LF/BFDF

SP/TO/JP


EC


HARGON 3610 ��$��\�<"#��" $�"��%'*"��


!�;�� [9��9��*��*��<j��j��j��j~=�0 - 20, step 0.5dB9��9��*��<%��%��%��%�~=�� 0 - 18, step 1.0dB

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0 - 20, step 0.5dBJ��<%�~=��7�]��_?9�*��+��)��<9>��9>��9>�=��7^��7~��?

vector.net 30

1. Typical value up to 1 GHz; 6,5 dB up to 1.2 GHz2.��-��*�-��@��(�� $&��--��]�!��3. Typical value, According to EN50083-3, 9 dB interstage slope, 42 channels CENELEC, 4. Full digital load 258 - 1218 MHz, 120 channels QAM 256, 12 dB slope5. Typical value up to f = 204 MHz6. For 5 – 60 MHz with DF 65-85 T7. K�� 7��?¡��_�7��~�!��+�)�^��!��*8.�9��_�7�^_�!��`��]�?�-��-��~��!��]�?��7��_�?��-��-��~��!�� +��)��?

��)��+��)��+)��+�)�^_�]_��#��`��_�' and present typical values




^_$��j��7�--��*��-�� with the plug-in modules

RF Parameters

Forward ChannelBandwidth 85...258 – 1218 MHzGain @1.2 GHz 40 ± 1 dBK��*��1 < 4.5 dBFlatness 2 ± 0.75 dBOutput level 3�'�?��7�^��?� '>J��7^��?��

114 dBμV114 dBμV


CINR = 41.5 dB 108 dBμV

9��< 7��= - 20 ± 1 dBJ��<��= - 20 ± 0.5 dB

Reverse ChannelBandwidth 5 – 65...204 MHzGain 26 dB ± 1 dBK��*��5 < 6.5 dBFlatness 6 ± 0.75 dBNPR / Dynamic range 7 50 dB / 23 dB


Others ��*��*��+��* 30 – 65 V ACMax. current for RF ports / AC IN 8 / 8 AReturn loss 8 > 18 dBPower consumption < 13.5 WOperation temperature range - 40 – 60 °CConnectors 3 x PG11 Protection class IP 67$��<}�#�"�#��=� 218 x 204 x 87 mmWeight 1.5 kg

JP/CS/EQ1

AT1 EQ2 EQ3AT2

AT3AT4

EQ4

EQ5

SP/TO/JP

LF/BF

DF DFIS

IS/JP

VIG

SMPS

TP -20 dB

TP -20 dB

AC IN

HARGON 351�"��[��<��%'*"��


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vector.net 31

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1.��_�!�� )��*�-��@��(��-��)��#��2. According to EN50083-3, 9 dB interstage slope, 42 channels CENELEC, typical value3. ��%%K��<'�?�'>J��]��]=��%%K��<'�?�'>J��^��]=��%%K��<'�?�'>J��~��]=�4.��]�?�-��-��~��!��]�?�7��_�?��-��-��~��!��5. 7 MHz < f < 63 MHz6.��^�?�-��_��]�!��`��]�?�-��-��]�!��_�?��-��-��~��!��7. For f >18 MHz, remote current < 8A @25ºC, typical value8. With NMS transponder 30 – 65 V AC9. Without NMS transponder @25ºC @65 V AC, GREEN 0; 31W = GREEN 1; 28W = GREEN 2

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NMS transponder��*��)��)��*��*��


CMS (Craft Management Software) compliant An easy and convenient process of network documentation thanks to the CMS software

RF Parameters

Forward ChannelBandwidth 85...260 – 1006 MHzGain @1 GHz 2 x 43 ± 0.75 dBK��*��(�� < 8 dBFlatness 1 ± 0.75 dBSlope ± 1 dB Output level 2,3�'�?��7�^��?� '>J��7�^��?��

118 dBμV118 dBμV

Return loss 4 > 18 dB9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 0.5 dB&��+��*��<j=��<%=��A1, E1A2, A3E2, E3

0 – 20 step 0.5 dB0 – 20 step 0.5 dB0 – 15 step 0.5 dB

Reverse ChannelBandwidth 5 – 65...200 MHzFlatness 5 ± 0.75 dBReturn loss 6 > 18 dBGain 25 / - 11 dBHUM modulation 7 ��7�^��?��*��<j=��<%=��A4, A5, A6, E4 0 – 20 step 0.5 dB

Available VersionsHARGON 2730 remote poweringHARGON 2730 mains powering

Others ��*��*��Remote powering 8

Mains powering30 – 65 V AC

230 ± 10% V ACMax. current for RF ports 10 AMax. current for AC IN port 12 APower consumption 9 36 WOperation temperature range - 40 – 60 °CConnectors ��<��)��@��=�Protection class IP 67$��<}�#�"�#��=� 245 x 215 x 91 mmWeight 3 kg


HARGON 2730�"#��" $�"��%'*"��

2 active outputs, 1 GHz / 200MHz

GREEN 2GREEN 1GREEN 0


μP Controller

A2 E2

A3 E3

E1

A1

HPB

BHHT

ATG 0CS

DF XXG

DF XXG

DF XXG

E4

LREQ A6 TP -20dB

RBPL

LPBL

NMS TRANSPONDER

A5 IS2

A4 IS1

TP -20dB

TP OUT2-20dB

TP OUT1-20dB

SWITCH MODEPOWER SUPPLY

NMS

VIG

INPUT

4A

10A

LOCAL AC INPUTOUTPUT 2 OUTPUT 1

10A

10A

vector.net 32

1.��_�!�� )��*�-��@��(��-��)��#��2. According to EN50083-3, 9 dB interstage slope, 42 channels CENELEC, typical value3.��]�?�-��-��~��!��]�?�7��_�?��-��-��~��!��4. 7 MHz < f < 63 MHz5.��^�?�-��_��]�!��`��]�?�-��-��]�!��_�?��-��-��~��!��6. For f >18 MHz, remote current < 8A @25ºC, typical value7. With NMS transponder 30 – 65 V AC8. Without NMS transponder @25ºC @65 V AC for max output level = 116 dBμV

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RF Parameters

Forward ChannelBandwidth 85...260 – 1006 MHzGain @1 GHz 2 x 40 ± 0.75 dBK��*��(�� < 8 dBFlatness 1 ± 0.75 dBSlope ± 1 dB Output level 2�'�?��7�^��?� '>J��7^��?��

116 dBμV117 dBμV

Return loss 3 > 18 dB9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 0.5 dB&��+��*��<j=��<%=��A1, E1A2, A3E2, E3

0 – 20 step 0.5 dB0 – 20 step 0.5 dB0 – 15 step 0.5 dB

Reverse ChannelBandwidth 5 – 65...200 MHzFlatness 4 ± 0.75 dBReturn loss 5 > 18 dBGain 25 / - 11 dBHUM modulation 6 ��7�^��?��*��<j=��<%=��A4, A5, A6, E4 0 – 20 step 0.5 dB

Available VersionsHARGON 2710 remote powering

Others ��*��*��Remote powering 7 30 – 65 V AC

Max. current for RF ports 10 AMax. current for AC IN port 12 APower consumption 8 36 WOperation temperature range - 40 – 60 °CConnectors ��<��)��@��=Protection class IP 67$��<}�#�"�#��=� 245 x 215 x 91 mmWeight 3 kg


200 MHz technology A possibility of extending bandwidth in upstream up to 200 MHz





HARGON 2710�"#��" $�"��%'*"��

2 active outputs, 1 GHz / 200 MHz

μP Controller

A2 E2

A3 E3

E1

A1

HPB

BHHT

ATG 0CS

DF XXG

DF XXG

DF XXG

E4

LREQ A6 TP -20dB

RBPL

LPBL

NMS TRANSPONDER

A5 IS2

A4 IS1

TP -20dB

TP OUT2-20dB

TP OUT1-20dB


NMS

VIG

INPUT

4A

10A

LOCAL AC INPUTOUTPUT 2 OUTPUT 1

10A

10A

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vector.net 33

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1.�K�&��]?�-��-��]^�!��`�K�&��]�_?�-��-��!��(��2.��_!��-��)��*�-��@��(��-��)��#��3. According to EN50083-3, 9dB interstage slope, 42 channels CENELEC, value measured & guaranteed per each product4.��%%K��<'�?�'>J��~��]=��%%K��<'�?�'>J��]=��%%K��<'�?�'>J��_=�5.��]?�-��-��~�!��]?�7��_?��-��-��~�!��6.�7��7��_?7. For 5 – 60MHz with DF65G8. >16dB for 5MHz < f < 8MHz; > 18dB for f > 8MHz9.�&��)��)`��7��?10. For f >16MHz, remote current < 6A @25ºC, typical value11. With NMS transponder 30 – 65V AC12. Without NMS transponder13. $��+�)�+��*�)�*��^�#��#��

��)��+��+�)�^_�]_��#��+�)��J��J��%%K�� at room temperature 25°C

LED Indicator%��(��*�� (��*� ��"%$�9��

RF Parameters

Forward ChannelBandwidth 85...260 – 1006 MHzGain @1 GHz 40 ± 0.75 dBK��*��1 < 8.0 dBFlatness 2 ± 0.75 dBSlope ± 1 dB Output level 3,4�'�?��7�^��?� '>J��7^��?��

114 dBμV118 dBμV

Return loss 5 > 18 dB9��< 7��=�6 - 20 ± 1.5 dBJ��<��= - 20 ± 0.5 dB&��+��*��<j=��<%=��A1, E1A2, E2

0 – 20 step 0.5 dB 0 – 15 step 0.5 dB

Reverse ChannelBandwidth 5 – 65...200 MHzFlatness 7 ± 0.75 dBReturn loss 8 > 18 dBGain 9 26 / - 8 dBHUM modulation 10 ��7�^��?��*��<j=��<%=��A3, A4, E3 0 – 20 step 0.5 dB

Available VersionsHARGON 2630 remote poweringHARGON 2630 mains powering

Others ��*��*��Remote powering 11

Mains powering24 – 65 V AC

230 ± 10% V ACMax. current for RF ports 10 AMax. current for AC IN port 12 APower consumption 12 18 WOperation temperature range - 40 – 60 °CConnectors ��<��)��@��=�Protection class IP 67$��<}�#�"�#��=�13 245 x 199 x 90 mmWeight 2.4 kg

1GHz technologyAn extended bandwidth in downstream up to 1 GHz








Control buttons

LED DISPLAY

BHHT

μP Controller

A2 E2 HPB

GREEN 2GREEN 1GREEN 0E1

A1

ATG0CS

E3

RBPL

LPBLLREQ A4TP -20dB

A3 IS1

DF XXG

DF XXG

NMS

VIGTP -20dB

LTI / LTO 1004 / ATG 0

INPUT BY-PASS

10A

10A

NMS TRANSPONDER


10A

10A

LOCAL AC INPUT

4A

TP -20dB

LTO / ATG 0

OUTPUT 2 OUTPUT 1

HARGON 2630�"#��" $�"��%'*"��

1 active output, 1GHz / 200MHz

vector.net 34

��K�&��]�?�-��-��]^��!��`�K�&��]�_�?�-��-��!��(��_�!��-��)��*�-��@��(��-��)��#��3. According to EN50083-3, 9 dB interstage slope, 42 channels CENELEC, value measured & guaranteed per each product ~��]�?�-��-��~��!��]�?�7��_�?��-��-��~��!��_��7��7��_�?6. For 5 – 60 MHz with DF65G7. >16 dB for 5 MHz < f < 8 MHz; > 18 dB for f > 8 MHz]��&��)��)`��7��?9. For f >16 MHz, remote current < 6A @25ºC, typical value10. With NMS transponder 30 – 65V AC11. Without NMS transponder��$��+�)�+��*�)�*��^�#��#��

��)��+��)��+)��+�)�^_�]_��#�� without TO on OUTPUT, at room temperature 25°C

RF Parameters

Forward ChannelBandwidth 85...260 – 1006 MHzGain @1 GHz 40 ± 0.75 dBK��*��1 < 8.0 dBFlatness 2 ± 0.75 dBSlope ± 1 dB Output level 3,�'�?��7�^��?� '>J��7�^��?��

114 dBμV118 dBμV

Return loss 4 > 18 dB9��< 7��=�5 - 20 ± 1.5 dBJ��<��= - 20 ± 0.5 dB&��+��*��<j=��<%=��A1, E1A2, E2

0 – 20 step 0.5 dB 0 – 15 step 0.5 dB

Reverse ChannelBandwidth 5 – 65...200 MHzFlatness 6 ± 0.75 dBReturn loss 7 > 18 dBGain 8 26 / - 8 dBHUM modulation 9 ��7�^��?��*��<j=��<%=��A3, A4, E3 0 – 20 step 0.5 dB

Available VersionsHARGON 2610 remote powering

Others ��*��*��Remote powering 10 24 – 65 V ACMax. current for RF ports 10 AMax. current for AC IN port 12 APower consumption 11 18 WOperation temperature range - 40 – 60 °CConnectors ��<��)��@��=�Protection class IP 67$��<}�#�"�#��=�12 245 x 199 x 90 mmWeight 2.4 kg

LED Indicator%��(��*�� (��*� ��"%$�9��







Control buttons

LED DISPLAY

BHHT

μP Controller

A2 E2 HPB

E1

A1

ATG0CS

E3

RBPL

LPBLLREQ A4TP -20dB

A3 IS1

DF XXG

DF XXG

NMS

VIGTP -20dB

LTI / LTO 1004 / ATG 0

INPUT BY-PASS

10A

10A

NMS TRANSPONDER


10A

10A

LOCAL AC INPUT

4A

TP -20dB

LTO / ATG 0

OUTPUT 2 OUTPUT

HARGON 2610�"#��" $�"��%'*"��


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vector.net 35

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1.�K�&��]�?�-��-��!��(��2.��_�!��-��)��*�-��@��(��-��)��#��3. According to EN50083-3, 9 dB interstage slope, 42 channels CENELEC, value measured & guaranteed per each product 4.��]�?�-��-��~��!��]�?�7��_�?��-��-��~��!��5. For 6 – 60 MHz with DF65G 6. >16 dB for 5 MHz < f < 8 MHz; > 18 dB for f > 8 MHz7. &��)��)`��7��?8. For f >16 MHz, remote current < 6A @25ºC, typical value9.��!��+�)��#��(��K&��-��-��!��


RF Parameters

Forward ChannelBandwidth 85...260 – 1006 MHzGain @1 GHz 1 x 39 ± 1 dBK��*��1 < 8 dBFlatness 2 ± 0.75 dBSlope ± 1 dB Output level 3�'�?��7�^��?� '>J��7^��?��

112 dBμV115 dBμV

Return loss 4 > 18 dB9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 0.5 dB&��+��*��<j=��<%=��A1, E1A2, E2

0 – 20 step 0.5 dB0 – 15 step 0.5 dB

Reverse ChannelBandwidth 5 – 65...200 MHzFlatness 5 ± 0.5 dBReturn loss 6 > 18 dBGain 7 26 / - 8 dBHUM modulation 8 ��7�^��?��*��<j=��<%=��A3, A4, A5, E3 0 – 20 step 0.5 dBK��*�� 9 < 6 dB

Available versionsHARGON 261 089Y remote poweringHARGON 261 089M mains powering

Others ��*��*��remote powering mains powering

30 – 65 V AC230 ± 10% V AC

Max. current for RF ports 7 AMax. current for AC IN port 8 APower consumption < 13 WOperation temperature range - 40 – 60 °CConnectors ��<��)��@��=Protection class IP 65$��<}�#�"�#��=� 202 x 172 x 80 mmWeight 2 kg

LED Indicator%��(��*�� (��*� ��"%$�9��


200 MHz technology A possibility of extending bandwidth in upstream up to 200 MHz




HARGON 261�"#��" $�"��%'*"��


vector.net 36

1.�j��]^��!��-��)��*��-�j">'��*��+�)��#��2. ALSC - automatic level & slope control 3. Typical value 4. Slope for 85 ± 862 MHz with 3 x DF 65A, 1 x RA G65, 1 x EQ 808G 5. According to EN 50083-3, 9 dB interstage slope, 42 channels CENELEC, typical value 6.��]?�-��-��~��!��`��]�?�7��_�?��-��-��~��!�� Z�7��~�?�7. Slope for 8 ± 65 MHz with 3 x DF 65A, 1 x RA G65, 1 x EQ 808G

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RF Parameters

Forward Channel TRUNK BRIDGEBandwidth 47…85 – 862 MHzGain @862 MHz 1 30 ± 1 dB 37 ± 1 dBALSC control range 2 6 dBK��*��3 ��^�?Flatness ± 0.4 dB ± 0.75 dBSlope 4 11 ± 1 dB Output level 5�'�?��7�^��?� '>J��7^��?��

110 dBμV112 dBμV

Return loss 6 Z��]�?9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 0.5 dB

Reverse ChannelBandwidth 5 – 30...65 MHzReturn loss 6 Z��]�?Gain 30 ± 1 dBK��*�� ?HUM modulation @ 12A 3 5 – 15 MHz 15 – 65 MHz85 – 862 MHz

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Slope 7 2 dB

Available VersionsGAMMA PRO 40 F86V remote powering

Others AC voltage range 35 – 65 V ACMax. current for RF / AC IN port 12 APower consumption 42 WOperation temperature range - 40 – 60 °CConnectors ~�#�_�]�&�<��)��@��=Protection class IP 67$��<}�#�"�#��=� 245 x 215 x 115 mmWeight 4.2 kg

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2 active output stage, 3 output ports

MESFET GaAs technology

Automatic Level and Slope Control unit

IP 67 die-cast compact housing

12 A power passing

ALSC - Automatic Level and Slope Control

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GAMMA PRO 40��$��%'*"��2 active outputs

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1.�$��#��$&��;��j��]��j��]��(��2. According to EN 50083-3; 9 dB interstage slope, 42 channels CENELEC, typical value3.��]�?�-��-��~��!��]�?�7��_�?��-��-��~��!�� Z��?4.��j��7��

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RF Parameters

Forward ChannelBandwidth 47...85 – 862 MHzGain @862 MHz 3 x 38 ± 0.75 dBK��*��1 < 7 dBFlatness 1 ± 0.75 dBSlope 1 ± 1 dB Output level 2�'�?��7�^��?� '>J��7^��?��

110 dBμV110 dBμV

Return loss 3 18 dB9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 1.0 dB

Reverse ChannelBandwidth 5 – 30...65 MHzFlatness ± 0.75 dBReturn loss 18 dBGain 20 ± 0.75 dB��!�� j�¢?�£�<��+��*=��5 – 15 MHz15 – 65 MHz85 – 862 MHz ��!��¢?�£�<��+��*=

��7�__�?��7�^��?��7�^��?��7��?�

Available VersionsGAMMA U8X-33A-AF8 remote poweringGAMMA U8M-33A-AF8 mains powering

Others j'��*��*��remote powering mains powering

30 – 65 V AC230 ± 10% V AC

Max. current for RF ports 12 AMax. current for AC IN port 15 APower consumption 4

remote powering mains powering

38 W37 W

Operation temperature range - 40 – 60 °CConnectors ��<��)��@��=Protection class IP 67$��<}�#�"�#��=� 245 x 204 x 130 mmWeight 4.3 kg

3 active outputs

Separate RF slope and level control

Remote or local powering, mains powering


ASC/AGC controlled by pilot tone

Optional Network Management Transponder (HMS)

High output level with excellent performance

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4 3

125

4 3

2

1

1

122

EQ2 EQ3 EQ4

AGC (option)

HPG 65EQ1 ATG

ATG ATG ATG

RF in

RF out

NMS2CONNECTOR

REVERSECONFIGURATION

MODULE

REVERSEAMPLIFIERMODULE

RHP1

RHP2 TP7

TP6

TP5

ISG2

ISG3

ISG4

AUTOLINK

AUTOLINK

AUTOLINK

ATG

ATG

ATG

DF

DF

DF

TP2 -20dB TP3 -20dB TP4 -20dB

OUTPUT2 OUTPUT3 OUTPUT4

12A

12A

12A

RAG 29-1 RCG 01

IBG

ATG

ATG

DF

REQTP

-20dB

INPUT

DC Voltage

SMPS

PSG 65

PSG 230

AC IN12A

DC Voltage

SMPS

187-253VAC

Remote powering version

Mains powering version

GAMMA U33�"#��" $�"��%'*"��

Current passing capability from RF ports and AC IN port

vector.net 38

1.��_�!�� )��*�-��@��(��-��)��#��2. According to EN50083-3, 9 dB interstage slope, 42 channels CENELEC, typical value3. �]�?�-��-��~��!��`��]�?�7��_��-��-��~��!��4. > 16 dB for f 5 – 8 MHz5.�&��)�<��*��j��*��=��)6. For f >18 MHz, remote current < 6A @25ºC, typical value7. }�)��+�)��j


RF Parameters

Forward ChannelBandwidth ~��]_��]^��Gain @862 MHz 2 x 38 ± 0.75 dBK��*��(�� < 7.5 dBFlatness 1 ± 0.6 dBSlope ± 1 dB Output level 2�'�?��7�^��?� '>J��7^��?��

114 dBμV114 dBμV

Return loss 3 �Z��]�?9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 0.75 dB

Reverse ChannelBandwidth 5 – 30...65 MHzFlatness ± 0.75 dBReturn loss 4 �Z��]�?Gain 5 18 / - 7 dBHUM modulation 6 ��7�^��?

Available VersionsBETA PRO 30 F89Y remote powering

Others j'��*��*�� 24 – 65 V ACMax. current for RF ports 15 AMax. current for AC IN port 10 APower consumption 7 34 / 36 WOperation temperature range - 40 – 60 °CConnectors ��<��)��@��=Protection class IP 67$��<}�#�"�#��=� 245 x 204 x 91 mmWeight 3 kg

2 active outputs


The same pads for slope and attenuation (ATG)

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Additional BY-PASS at the input

ATG

(OR)

ISG

CS

RHP

DF RA

TP -20dB

10A3.15A

INPUT OUTPUT 1OUTPUT 2BYPASS

LOCAL AC INPUT

TP


10A10A

10A

TP -20dB TP -20dB

(OR)

DF

ISG

ATG

ATG

ATGA TG

ATG

ATG

ATG

ATG

AUTO LINK

TI / TO 804 / AT 800

AUTO LINK

DFATG

ATG

BETA PRO 30�"#��" $�"��%'*"��

2 active outputs

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1. ��_�!�� )��*�-��@��(��-��)��#��2. According to EN50083-3, 9 dB interstage slope, 42 channels CENELEC, typical value3.��]�?�-��-��~��!��`��]�?�7��_��-��-��~��!��4. > 16 dB for f 5 – 8 MHz5. &��)�<��*��j��*��=��)6. For f > 18 MHz, remote current < 6A @25ºC, typical value7.�}�)��+�)��j


RF Parameters

Forward ChannelBandwidth BETA PRO 20 BETA PRO 21

~��]_��]^��_��]_��]^��

Gain @862 MHz BETA PRO 20 BETA PRO 21

38 ± 0.75 dB40 ± 0.75 dB

K��*��(�� < 7.5 dBFlatness 1 ± 0.6 dBSlope ± 1 dB Output level 2�'�?��7�^��?� '>J��7^��?��

114 dBμV114 dBμV

Return loss 3 �Z��]�?9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 0.75 dB

Reverse ChannelBandwidth BETA PRO 20 BETA PRO 21

5...30 – 65 MHz_��__��^_��

Flatness ± 0.75 dBReturn loss 4 ��]�?Gain 5 22 / - 3 dBHUM modulation 6 ��7�^��?�

Available VersionsBETA PRO 20 F89Y gain 38 dBBETA PRO 21 F89Y gain 40 dB

Others j'��*��*�� 24 – 65 V ACMax. current for RF ports 15 AMax. current for AC IN port 10 APower consumption 7 18 / 20 WOperation temperature range - 40 – 60 °CConnectors ��<��)��@��=Protection class IP 67$��<}�#�"�#��=� 245 x 204 x 91 mmWeight 2.9 kg


The same pads for slope and attenuation (ATG)

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CS

DF

TP -20dB

INPUT OUTPUT 1OUTPUT 2BYPASS

TI / TO 804 / AT 800


TP

RHP

AUTO LINK

ISG

LOCAL AC INPUT

3.15A

TO / AT 800

(OR)

TP -20dB

(OR)

10A

10A

10A

10A

DF

ATGA TG

ATGA TG

ATG

ATG

ATG

BETA PRO 20/21�"#��" $�"��%'*"��

1 active output

vector.net 40

1. ��!��+�)��#��(��2.�>��*�-��@��(�� $&��7�-� ��¤'3.�j��*��%K_��]�7��?��*��@��~��)��'%K%"%'��%%K��4.��]�?�-��-��~��!��`��]��_�?��-��-��~��!��9K��J&&5. Active6. For f > 7 MHz7.��!��+�)��#��(��K&��-��-��!��8. GREEN 0 = 112 dBμV; 9W for GREEN 1 = 109 dBμV; 7W for GREEN 2 = 106 dBμV;



200MHz technology A possibility of extending bandwidth in upstream up to 200 MHz;DOCSIS 3.1 standard compliant


RF Parameters

Forward ChannelBandwidth 85...260 – 1006 MHzGain @1 GHz 38 ± 1 dBK��*��(��1 < 6.5 dBFlatness 2 ± 0.75 dBSlope ± 1 dB Output level @ 862 MHz3�'�?��7�^��?� '>J��7�^��?��

112 dBμV112 dBμV

Return loss 4 > 18 dB9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 0.5 dB&��+��*��<j=��<%=�� j��%��<j��= A2,%��<;��=

0 – 20 step 1 dB0 – 15 step 1 dB

0 / 6 / 9 dB

Reverse ChannelBandwidth 5 – 65...200 MHzFlatness ± 0.75 dBReturn loss 4 > 18 dBGain 5 26 dBHUM modulation 6 ��7�^_�?��*��<j=��<%=��j��j~��%��<j��=

0 – 20 step 1 dB

K��*�� 7 < 6 dB

Available VersionsHARGON 2410 069W PG11/F, remote poweringHARGON 2410 059M F/F, mains powering

Others ��*��*��remote poweringmains powering

30 – 65 V AC230 ± 10% V AC

Power consumption 8 < 11 WOperation temperature range - 40 – 60 °CConnectors PG11 Protection class IP 65$��<}�#�"�#��=� 202 x 172 x 80 mmWeight 0.8 kg

VIG (VECTOR INGRESS GUARD) system compliant ��-��)��-��*��)��+��

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A10-20dB

E10-20dB

A20-15dB

E20/6/9 dB

RBPL

DF DF

OUTPUTINPUT 230V AC

A50-20dB

IS

A40-20dB

E30-20dB

A30-20dB

POWER

TP -20dB TP -20dB

SMPS

SMPS

ON / OFF

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vector.net 41

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1. Typical value2. Valid in range 110 – 862 MHz3. Measured in range 110 – 862 MHz4. ��?��@��*��%K_��]�7��^�?��*��~��)��'%K%"%'��(��5. �]�?�-��-��~��!��]�?�7��_�?��-��-��~��!��6. Without connectors

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RF Parameters

Forward ChannelBandwidth 85 – 862 MHzGain @862 MHz 36 ± 1 dBK��*��1 < 8.5 dBFlatness 2 ± 0.75 dBSlope3 6 ± 1 dB Output level @ 862 MHz4�'�?��7�^��?� '>J��7�^��?��

109 dBμV108 dBμV

Return loss5 > 18 dB9��< 7��= - 20 ± 1.5 dBJ��<��= - 20 ± 1 dB

Reverse ChannelBandwidth 5 – 65 MHzFlatness ± 0.75 dBGain 20 ± 1 dBHUM modulation 1 ��7�^��?�

Available Versions

LAMBDA PRO 20 F66W �#��*7�� remote powering 24 – 65 V AC, connectors PG11/F

LAMBDA PRO 20 F76W �#��*7�� remote powering 24 – 65 V AC, connectors 5/8

LAMBDA PRO 20 F56M �#��*7�� mains powering 230 V AC, connectors F/F

LAMBDA PRO 20 V66W variable adjustment, remote powering 24 – 65 V AC, connectors PG11/F

LAMBDA PRO 20 V56M variable adjustment, mains powering 230 V AC, connectors F/F

Others j'��*��*��version F66W / F76W / V66Wversion F56M / V56M

24 – 65 V AC230 ± 10% V AC

Power consumption version F66W / F76W / V66W version F56M / V56M

8 W8.5 W

Operation temperature range - 40 – 60 °C'��9K�J��version F66W / V66W version F56M / V56Mversion F76W

PG11/FF/F

5/8”Protection class IP 65$��<}�#�"�#��= 6 157 x 136 x 69 mm}�*)��version F66W / F76W/ V66W version F56M / V56M

0.9 kg1.3 kg


High protection class IP 65

Fixed plug-in modules or adjustable embedded elements

External test points

Compact housing

6dB

DF

INPUT OUTPUT

75R



DF

2TP - 0dB 2TP - 0dB2TP - 0dB

230V AC

EQ10-18dB

EQ20-18dB

AT10-18dB

A20-18dB

ATG 6dB

DF

INPUT OUTPUT

75R



DFATGATG

ATG

230V AC

2TP - 0dBfor F56M, F76M

for F66W, F76W only for F66W

only for F56M

LAMBDA PRO 20 V56MLAMBDA PRO 20 V66W

LAMBDA PRO 20 F56MLAMBDA PRO 20 F66W LAMBDA PRO 20 F76W

LAMBDA PRO 20;�<��%'*"��

1 active output, 862 MHz / 65 MHz

vector.net 42

1. Typical value2. Valid in range 110 – 862 MHz3. According to EN50083-3, 42 channels CENELEC, 0 dB interstage slope, typical value4.��~�?�-��-��~��!��~�?�7��_�?��-��-��~��!��5.�&��-��^��!��`��^�?�-��-��^_�!��_¥'6. According to DIN 45004B, typical value7. For 0.03 – 1 GHz according to EN50083-28. Including connectors

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RF Parameters

Forward ChannelBandwidth 85 – 862 MHzGain @862 MHz 30 ± 1 dBK��*��1 ��^�_�?Flatness 2 ± 0.75 dBOutput level @ 862 MHz3�'�?��7�^��?� '>J��7�^��?��

101 dBμV101 dBμV

Reverse ChannelBandwidth 5 – 65 MHzReturn loss 4 > 14 dBK��*�� 5 ��_�?Flatness ± 0.75 dBGain 25 ± 1 dBOutput level 6�9!$��7�^��?� 9!$��7�^��?�

105 dBμV117 dBμV

HUM modulation 1 ��7�^��?�

Others ��*��-��;��forward attenuation AT1-��+��@��%��reverse attenuation AT2

0 – 18 dB0 – 18 dB0 – 10 dB

Radiation 7 20 dBpWAC voltage range 230 ± 10% V ACPower consumption 5.5 WOperation temperature range - 20 – 60 °CConnectors FProtection class IP 40$��<}�#�"�#��= 8 120 x 155 x 55 mm}�*)�� 0.6 kg


Built-in active reverse path

Variable adjustment

Compact housing

EQ10-18dB

AT10-18dB

AT2AMIGO M865 A30 0-180dB

INPUT OUTPUT

DF DF


230V AC

AMIGO A;�<��%'*"��


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vector.net 43

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1. Typical value2. For CTB < - 60 dB i CSO < - 60 dB, for 42 channels CENELEC at T = 25°C3.��~�?�-��-��~��!��~�?�7��_�?��-��-��~��!�� Z��?4. Max. for 230 V5. Including connectors

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RF Parameters

Forward PathBandwidth M800 P30 / P36 M830 P30M865 P30 / P36

47 – 862 MHZ47 – 862 MHZ85 – 862 MHZ

Gain @862 MHz M800 / M830 / M865 P30M800 / M865 P36

30 ± 1 dB36 ± 1 dB

K��*��1 < 7 dB!�#��$9K�<~_��~�?= 117 dBμVOutput level 2�'�?��7�^��?� '>J��7�^��?��

102 dBμV102 dBμV

Reverse PathBandwidth M830 P30 / P36 M865 P30 / P36

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Passive attenuation M830 P30, M865 P30 / P36 < 1.5 dBReturn loss 3 > 14 dB

Others ��*��-��;��forward attenuation AT1-��+��@��%��

0 – 18 dB0 – 18 dB

AC voltage range 230 ± 10% V ACPower consumption 4

M800 / M830 / M865 P30 M800 / M865 P36

8 W9 W

Operation temperature range - 20 – 60 °CConnectors FProtection class IP 40$��<}�#�"�#��= 5 120 x 135 x 55 mm}�*)�� 0.6 kg

Available Versions

AMIGO M 800 P30 Forward path bandwith 47 – 862 MHz, gain 30 dB

AMIGO M 800 P36 Forward path bandwith 47 – 862 MHz, gain 36 dB

AMIGO M 830 P30 Forward path bandwith 47 – 862 MHz, gain 30 dB; Reverse path bandwith 5 – 30 MHz

AMIGO M 865 P30 Forward path bandwith 85 – 862 MHz,gain 30 dB; Reverse path bandwith 5 – 65 MHz

AMIGO M 865 P36 Forward path bandwith 85 – 862 MHz, gain 36 dB; Reverse path bandwith 5 – 65 MHz

High quality performance

Stability of technical parameters

Variable adjustment

Compact housing

EQ10-18dB

AT10-18dB

INPUT OUTPUT

DF DF


230V AC

only for AMIGO M 865 P30 / 36, AMIGO M 830 P30

AMIGO P;�<��%'*"��


vector.net 44

VECTOR Ingress Guardsimple and intuitive solution

for locating the sourceof ingress

vector.net 45

HEADENDEQUIPMENT

CONTROLLER

MANAGEMENT SOFTWARE

INGRESSSTOP

BOOSTRAL 6700

INGRESS

HARGON 2400

HARGON 2400

HARGON 2400

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1. Reduce the time services are unavailable to subscribers 2. Reduce defect correction costs 3. Reduce the quantity of subscribers affected during the occurrence of ingress 4. Exploit the return channel bandwidth more effectively

Ingress is a problem which occurs in every cable television network. Whenever it is present there are generally serious operational issues, including the most consumer sensitive one - the disturbance of upstream communication of cable modems. In a highly competitive Broadband market, Quality of Service is vital to customer retention ��+��@��7�)�� *�9�*��(�-��Operators across the world.

How system works

The ingress switch system provides a simple and intuitive solution to locate the source of ingress in the coaxial cable distribution plant of an HFC network. It comprises of Headend Controller, Web Based application and IS plant modules installed in ampli-��)�� -��@�� )��-��convenient solution for ensuring network reliability by detecting, locating, and resolving ingress in a matter of minutes.

Headend Controller

The HEADEND unit is a powerful headend microcomputer witch embedded WEB-server. The Control Unit controls the status of addressable IS modules.

Wideband FSK receiver with IS

The “IS modules” modules are return path switches that can be installed in the VECTOR ��;�� -�� #��-��)��*��*��)��)��$��*��-��#��*��)��-��(��@��+�)��(�to add a new line of devices in the cable plant.

VIG Software }%?7 ��-�+��9�+)��)��+��*��be created and stored in a database and seen in a graphical way. The “VIG SOFT-WARE” allows to controll the HEC locally or remotely via Ethernet / SNMP.

Small size of the FSK receiver and IS module enables ��>�� + � ��

Low power consumption of the FSK receiver

No necessity for changes in the power system thanks to the low power consumption of modules

Widely adjustable range of transmitted frequency of the HEC

�;�� #�+ �>�� [�� ;��+�� (for network adjustment) and carrier with modulation (transmission)

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FSK detection function for status signaling

J>�� ;��<�;��+��## � ��+�� [ mixed and full digital loading

WEB SERVER application – an intuitive tool which allows the user to create a topology of the network �� >�� Q�� + �>��

VECTOR INGRESS GUARDIngress Detection System

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vector.net 46

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Forward path measurement range "�+�-��@��(��]_��]�!��_�!��*)�-��@��(��]_��]�!��_�!��

Measurement bandwidth 8 MHzMeasurement accuracy ± 0.5 dBSlope correction range ± 3 dBGain correction range ± 3.5 dBDetection mode CW, PAL, QAM, OFDMDigital Quality Index 10 @ 85 – 1218 MHz

General informationPower consumption 1.0 W

Automatic Level and Slope Control plug-in module #��<��"�� "�� measurements of two RF signals / pilots (typically placed at high and low part of frequency range)

FWD Level measurement

Fast and accurate level measurement unit can measure any forward path channel level, with selectable peak/average detection

ALSC pilot frequencies are user selectable

ALSC Module Automatic Level and Slope Control Module

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Monitored ParametersBOOSTRAL 7910

7810 7710

Using standard HMS MIBs rd / wrt

A/B switch ��Power RxA/RxB ��7Transmited optical power Tx1 / Tx2 / Tx3 / Tx4 ��7Optical transmitter laser current Tx1 / Tx2 / Tx3 / Tx4 ��7Ingress Switch 1, 2, 3, 4 ��Internal powering DC ��7Remote powering AC ��7Temperature ��7Tamper ��7Rx transponder level ��7Tx transponder level ��7

Using proprietary MIBsForward attenuators ��&��+��@�� Reverse attenuators ��@�� &��+��*�� *��

!�&Q�!�&��

Standards DOCSIS 2.0, EuroDOCSIS 2.0Power consumption < 5 W

Network communicationNetwork protocols IP, UDP, TCP, DHCP, TFTP SNMP v1, v2c

Embedded web interface Read Access MIB variables,Read-Write Access parameters

Easy implementation in DOCSIS/EuroDOCSIS environment

Embedded WWW page

Remote access monitoring via WWW page and/or monitoring software

SNMP v1, v2c compliant

Cost effective solution thanks to using existing HFC infrastructure

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DCM/EDCM T DOCSIS/EURODOCSIS Communication Module

vector.net 48

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Monitored Parameters

BETA PRO 60 G HARGON 2710HARGON 2730

HARGON 2610HARGON 2630

Using standard HMS MIBs rd / wrt rd / wrt rd / wrt

A/B switch �� – –Power RxA/RxB ��7 – –Transmited optical power Tx1/Tx2 ��7 – –Optical transmitter laser current Tx1/Tx2 ��7 – –Ingress Switch 1, 2 �� Internal powering DC ��7 ��7 ��7Remote powering AC ��7 ��7 ��7Temperature ��7 ��7 ��7Tamper ��7 ��7 ��7Rx transponder level ��7 ��7 ��7Tx transponder level ��7 ��7 ��7

Using proprietary MIBsForward attenuators �� &��+��@�� Reverse attenuators �� @�� *�� – –

!�&Q�!�&��

Standards DOCSIS 2.0, EuroDOCSIS 2.0

�#�-��@��(��*� 5 to 42 MHz DOCSIS5 to 65 MHz EuroDOCSIS

Channel bandwidth 6 MHz DOCSIS8 MHz EuroDOCSIS

��-��@��(��*� 91 to 857 MHz DOCSIS108 to 862 MHz EuroDOCSIS

Power consumption < 5 W

Network communicationNetwork protocols IP, UDP, TCP, DHCP, TFTPSNMP v1, v2cEmbedded web interface Read Access MIB variables,

Read-Write Access parameters

Ordering system

BETA PRO 60 G HARGON 2710HARGON 2730

HARGON 2610HARGON 2630

Monitoring module Monitoring kit Monitoring kit

Easy implementation in DOCSIS/EuroDOCSIS environment

Embedded WWW page

Remote access monitoring via WWW page and/or monitoring software

SNMP v1, v2c compliant

Cost effective solution thanks to using existing HFC infrastructure

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DCM/EDCM DOCSIS/EURODOCSIS Communication Module

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vector.net 49

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Monitored parameters

BETA PRO 60 GHARGON 2710HARGON 2730HARGON 2610HARGON 2630

GAMMA O33 GAMA U33

Using standard HMS MIBs rd / wrt rd / wrt rd / wrt rd / wrt

A/B switch �� – �� –Power RxA/RxB �� – �� –Transmited optical power Tx1/Tx2 �� – �� –

Optical transmitter laser current Tx1/Tx2 �� – �� –

Ingress Switch 1, 2 �� Internal powering DC ��7 ��7 ��7 ��7Remote powering AC ��7 ��7 ��7 ��7Temperature ��7 ��7 ��7 ��7Tamper ��7 ��7 ��7 ��7Rx transponder level ��7 ��7 ��7 ��7Tx transponder level ��7 ��7 ��7 ��7

Transponder parameters��-��@��( Agile, 40 – 120 MHzInput level range 40 – 80 dBμV��-��@��( 5 – 42 MHz&��@��(�� 0.1 %Output RF level 105, ± 3 dB @ max. dBμVOutput level attenuator -30 – 0.2 dB steps dB

Bandwidth 300 @ - 40 dBc kHz500 @ - 50 dBc kHz

Modulation type FSK, ± 50 kHz nominal

Modulation tolerance ± 2 kHz

Power consumption < 2 WStandard HMS

Ordering system

BETA PRO 60 GHARGON 2710HARGON 2730HARGON 2610HARGON 2630

GAMMA O33 GAMA U33

Monitoring module Monitoring kit Monitoring kit Monitoring kit

HMS complaint

Easy installation

Frequency agile RF modem

Remote and local upgrade capability

\� �� "� �+� �+��#��

Remote control Tx, Rx in transponder

HCM HCM Communication Module

vector.net 50

Monitored Parameters

BOOSTRAL 6610rd / wrt

Power Rx ��7Transmited optical power Tx ��7Optical transmitter laser current Tx ��7Ingress Switch ��Internal powering DC ��7Remote powering AC ��7Temperature ��7Rx transponder level ��7Tx transponder level ��7

1. Relative to transponder transmit carrier2. Referred to a 6 MHz measurement bandwidth

��)��+��_��'

HMS complaint

Easy installation

Frequency agile RF modem

Software upgrade capability

Remote control Tx, Rx in transponder


Transponder parameters&��@��(��*� Agile, 48 – 162 MHzModulation type FSKModulation tolerance ± 2 kHz&��@��(�� ± 50 or ± 67 kHzData rate 38.4 kbpsPower consumption < 1 WTemperature - 40 – 85 °C$��<}#"#�= 50 x 15 x 35.5 mm

ReceiverInput levels - 20 – 20 dBμVSpurious outputs - 15 max., 50 – 1006 MHz dBμV

TransmitterOutput levels 40 ± 3 dBμVOutput attenuator 0 – 30.2 dB step, ± 1 dB

Bandwidth 300 @ - 40 dB kHz500 @ - 50 dB kHz

Spurious outputs - 55 dBc max. ¹- 15 dBμV max., 5 – 88 MHz ²

ARRIS VALUE MAX HCM Communication Module

Acce

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vector.net 51

1. Communication via SNMP with DOCSIS/EuroDOCSIS transponder2.��)��+��-��)�� <"*)�=��-��<&��=��-��+++��

��)��+��_��'

System requirementsRAM 512 MBProcessor 1 GHzOperating system WINDOWS 2000/XP Vista/7HDD space 100 MBScreen resolution 1024 x 768 px

CMS licences

Light Full2

��+�*��*��on the HHT terminal � �

Copying data from the HHT to computer or from computer to HHT ��

��+�*��*��computer disk � �

Add comments and description of the location �-��)��)��

%#��)��+�)��#��#��or csv � �

Terminal HHT software update � �'��*��-��)��>?7��

$��+�� Changing the devices parameters by using remote communication via SNMP with ��@��+�)��)��DOCSIS/EuroDOCSIS or ethernet communications module

- ��

=��#�� over RS interface

��+��>�� data on the computer

Remote communication with network devices via SNMP

�� #�;��

�:��+ �� ;��+ :� �� txt or csv

Communication

RS interfacerd / wrt SNMPrd / wrt

BOOSTRAL 6610 �� 1

BETA PRO 60 G �� 1

LAMBDA PRO 71/72 ��1

HARGON 2710, HARGON 2730 �� 1

HARGON 2610, HARGON 2630 �� 1

Acce

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ices

CMSCraft Management Software

! �� ;��

User friendly

vector.net 52

Parameters

Power %#��-��>?��DC voltageOptional battery pack

5 V5 x AA

Display Graphical / LED blacklight 128 x 128 px

Keyboard alphanumeric

Portsj��J�� D-sub 9-pin PC connector mini USB type B

Universal device for setup and maintenance

An intuitive menu

Increase network documentation quality

Decrease installation time

OPEX savings in network installation and maintenance

Acce

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BHHTBasic hand held terminal

Others9��:��)��( up to 8 MBOperation temperature range -20 – 60 ºC$��<}#"#�= 214 x 100 x 35 mmWeight 0.375 kg

vector.net 53

Scheme of 1.2 GHzPlug-in Modules

Function =��>$��"�� Type

SP Splitter 4 4,5 dB T Plug-in for 1.2 GHz products

TO Tap out 6 6 dB T Plug-in for 1.2 GHz products

TI Tap in 6 6 dB T Plug-in for 1.2 GHz products

EQ Equalizer 1218 1218 MHz ET Electronic, Plug-in for 1.2 GHz products

JP Jumper 0 0 dB T Plug-in for 1.2 GHz products

AT Attenuator 1 1 dB T Plug-in for 1.2 GHz products

CS Cable simulator 1218 3 1218 MHz, 3,5 dB T Plug-in for 1.2 GHz products

BF ��%�� 15 - 204 15 - 204 MHz T Plug-in for 1.2 GHz products

LF =�;%�� 204 204 MHz T Plug-in for 1.2 GHz products

HF ��+%�� 258 258 MHz T Plug-in for 1.2 GHz products

DF !�� :�� 204 - 258 204 - 258 MHz T Plug-in for 1.2 GHz products

TX Transmitter C1310 3 CWDM 1310 nm, 3dBm T Plug-in for 1.2 GHz products

VIG VECTOR INGRESS GUARD A for BL7XXX T Plug-in for 1.2 GHz products

EDCM EURODOCSIS communication module A for BL7XXX T Plug-in for 1.2 GHz products

DCM DOCSIS communication module A for BL7XXX T Plug-in for 1.2 GHz products

Sche

me o

f 1.2

GHz

Plu

g-in

Mod

ules

vector.net 54

AT XX T / ATG 10XX ^ ^ ^ ^ ^ ^ ^ ^BF XX T/ RBPL XX G ^ ^ ^ ^ ^ ^ ^BF XXX T ^ ^ ^ ^ ^ ^ ^CS XXXX 3,6,9 T ^ ^ ^ ^DF XXX T ^ ^ ^ ^ ^ ^ ^ ÊQ XXXT/LREQ XX ^ ^ ^ ÊQ XXXX T ^ ^ ^ ^ ^ ^ ^ ^HF XXX T ^ ^ ^JP 0 T / ATG 1000 ^ ^ ^ ^ ^ ^ ^ ^JP 0 T 2 ^ ^ ^ ^ ^ ^ ^ ^LF XX T / LPBL XXG ^ ^ ^ ^ ^ ^ ^ ^LF XXX T ^ ^ ^ ^ ^ ^ ^ ^SP 4 T ^ ^ ^ ^ ^TO XX T ^ ^ ^ ^ ^TX C1XXX 3 T ^TX C1XXX 6 T ^ ÂGC XXX-X ^ ÂT 800 ^ ^ ^ ÂT 8XX ÂT 1000 ^ ÂTG 1000 ^ ^ ^ ÂTG 10XX ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^ ^BHHT ^ ^ ^ ^ ^ ^CS ^ ^ ^ ^ ^ ^DF XXA ^ ^ ^ ^ ^DF XXG ^ ^ ^ ^ ^ ^ ^ ^ ÊQ ^ ^ ^FTB ^HPB ^ ^ ^ ÎSG 65 ^ ^ ^ ^LPB ^ ^ ^ ^LREQ 200 ^ ^ ^ ^LTI 10XX ^ ^LTO 10XX ^ ^ ^ ÔFR ÔSR ÔFRB HG v2 ÔFRB LG v2 ÔRT ÔRTB ÔRTB / BL6610 ^RA 65 ^ ^RAG ^ ^ ^RBP ^ ^ ^ ^RBPL ^ ^ ^RCG XX ^ ^REQ XX ^ ^RHP ^ ^ ^ ^ ^RJP ^ ^ ^RP 600 ^ ^TI 8XX ^ ^TO 8XX ^ ^ ^TO 10XX ^VIG ^ ^ ^ x ^ x x x ^ ^ ^ ^ ^ ^ ^ ^ ^

BO

OST

RA

L 79

10

BO

OST

RA

L 78

10

BO

OST

RA

L 77

10

BO

OST

RA

L 66

10

BET

A P

RO

60G

GA

MM

A O

33

BO

OST

RA

L 75

1

BO

OST

RA

L 65

1

BO

OST

RA

L 61

1

OPT

IMER

451

0

LAM

BD

A P

RO

71/

72

LAM

BD

A P

RO

70

OPT

I

HA

RG

ON

381

0

HA

RG

ON

371

0

HA

RG

ON

361

0

HA

RG

ON

351

HA

RG

ON

273

0

HA

RG

ON

271

0

HA

RG

ON

263

0

HA

RG

ON

261

0

HA

RG

ON

261

GA

MM

A P

RO

40

GA

MM

A U

33

BET

A P

RO

30

BET

A P

RO

20/

21

HA

RG

ON

241

0

LAM

BD

A P

RO

20

AM

IGO

A /

P

x - ��@��

=��>$��"��Plug-in Modules

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vector.net 55

BOOSTRAL 7910 / BOOSTRAL 7810 / BOOSTRAL 7710

Parameter Value CommentLaser type DFB isolated}��*�)�ORTB C1310-SCA / BP 100GORTB C1330-SCA / BP 100GORTB C1350-SCA / BP 100GORTB C1370-SCA / BP 100GORTB C1390-SCA / BP 100GORTB C1410-SCA / BP 100GORTB C1430-SCA / BP 100GORTB C1450-SCA / BP 100GORTB C1470-SCA / BP 100GORTB C1490-SCA / BP 100GORTB C1510-SCA / BP 100GORTB C1530-SCA / BP 100GORTB C1550-SCA / BP 100GORTB C1570-SCA / BP 100GORTB C1590-SCA / BP 100GORTB C1610-SCA / BP 100G

1310 ± 1, - 2 nm

1330 ± 1, - 2 nm

1350 ± 1, - 2 nm

1370 ± 1, - 2 nm

1390 ± 1, - 2 nm

1410 ± 1, - 2 nm

1430 ± 1, - 2 nm

1450 ± 1, -2 nm

1470 ± 1, - 2 nm

1490 ± 1, - 2 nm

1510 ± 1, - 2 nm

1530 ± 1, - 2 nm

1550 ± 1, - 2 nm

1570 ± 1, - 2 nm

1590 ± 1, - 2 nm

1610 ± 1, - 2 nm

16 wavelength, other on ��@��

Wavelength temperature ��-�� 0.1 nm/ºC typical, max. 0.12

Node operation temperature rangeORTB CXXXX-SCA / BP 100G 3dBORTB CXXXX-SCA / BP 100G 6dB

- 40 – 55 ºC

- 40 – 50 ºC

Output optical powerORTB CXXXX-SCA / BP 100G 3dBORTB CXXXX-SCA / BP 100G 6dB

3 ± 0.5 dBm

6 ± 0.5 dBmBandwidth 5 – 200 MHzOptical connector type SC / APC J�)��@��

Alarm from reverse transmitter j ��(��

Test point RF - directional - 20 dB Relative to RF signal feeding transmitter

Stabilized optical power ± 0.5 dBmFluctuations in reverse

channel in headend. Typical value

OMI change in temperature function ± 0.5 dB

Fluctuations in reverse channel in headend.

Typical valuePower consumptionORTB CXXXX-SCA / BP 100G 3dBORTB CXXXX-SCA / BP 100G 6dB

< 1.5 W

< 2 W

Typical value

DFB CWDM optical transmitter module with OMI sta-bilization XXXX = 1310, 1330, 1350, 1370, 1390, 1410, 1430, 1450, 1470, 1490, 1510, 1530, 1550, 1570, 1590, 1610

ORTB CXXXX-SCA / BP 100G 3dBORTB CXXXX-SCA / BP 100G 6dB

RFOpticO

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TP -20dB

TX CXXXX, 3dB Available for BL7910, BL7810, BL7710

TX CXXXX, 6dB Available for FOR BL7810, BL7710

DFB CWDM optical transmitter module with OMI stabilizationXXXX 3 dB = 1310, 1330, 1350, 1370, 1390, 1410, 1430, 1450, 1470, 1490, 1510, 1530, 1550, 1570, 1590, 1610XXXX 6 dB = 1470, 1490, 1510, 1530, 1550, 1570, 1590, 1610

RFOpticO

E

TP -20dB

Parameter Value CommentLaser type DFB isolated

}��*�)�

1310 ± 1, - 2 nm1330 ± 1, - 2 nm1350 ± 1, - 2 nm1370 ± 1, - 2 nm1390 ± 1, - 2 nm1410 ± 1, - 2 nm1430 ± 1, - 2 nm1450 ± 1, - 2 nm

3 dBm 8 wavelengths

}��*�)�

1470 ± 1, - 2 nm1490 ± 1, - 2 nm1510 ± 1, - 2 nm1530 ± 1, - 2 nm1550 ± 1, - 2 nm1570 ± 1, - 2 nm1590 ± 1, - 2 nm1610 ± 1, - 2 nm

3 dBm, 6 dBm

8 wavelengths

Wavelength tempera-��-�� 0.1 nm/ºC typical, max. 0.12

Node operation temperature range -40 – 50 ºC

Output optical power3 ± 0.5 dBm

6 ± 0.5 dBm

3 dBm @16 wavelenghts <��7�^��=

6 dBm @8 wavelenghts <�~��7�^��=

Bandwidth 5 – 200 MHzOptical connector type SC / APC J�)��@��

Alarm from reverse transmitter j ��(��

Test point RF - directional - 20 dB Relative to RF signal feeding

the laser diode

Stabilized optical power ± 0.5 dBm

Fluctuations in reverse chan-nel in headend.

Typical value


Fluctuations in reverse chan-nel in headend.

Typical value

��+��TX C1XXX 3 TTX C1XXX 6 T

1.5 W2 W Typical value

Parameter Value CommentLaser type DFB IsolatedWavelength 1550 ± 20 nmOutput optical power 3 ± 0.5 dBmBandwidth 5 – 200 MHzOptical connector type SC / APC J�)��@��Alarm from reverse transmitter j ��(��

Test point RF - directional - 20 dB Relative to RF signal

feeding transmitter

Stabilized optical power ± 0.5 dBm

Fluctuations in reverse channel in headend .

Typical value


Fluctuations in reverse channel in headend. Typi-

cal valuePower consumption < 1.5 W Typical value

RFOpticO

E

TP -20dB

DFB 1550 nm optical transmitter module with OMI stabilization

ORTB 3D1550-SCA / BP 100G

ORTB 3D1310-SCA / BP 100GDFB 1310nm optical transmitter module with OMI stabilization

Parameter Value CommentLaser type DFB IsolatedWavelength 1310 ± 20 nmOutput optical power 3 ± 0.5 dBmBandwidth 5 – 200 MHzOptical connector type SC / APC J�)��@��Alarm from reverse transmitter j ��(��


feeding transmitter

Stabilized optical power ± 0.5 dBmFluctuations in reverse

channel in headend. Typi-cal value


Fluctuations in reverse channel in headend. Typi-

cal valuePower consumption < 1.5 W Typical value

RFOpticO

E

TP -20dB

BOOSTRAL 6610

Plug

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Plug-in ModulesFor BOOSTRAL 7910 / 7810 / 7710 / BETA PRO 100G

Parameter Value CommentLaser type FP IsolatedWavelength 1310 ± 40 nmOutput optical power 0 – 0.5 dBmBandwidth 5 – 200 MHzOptical connector type SC/APC J�)��@��Alarm from reverse transmitter j ��(��


feeding transmitter

Stabilized optical power ± 0.5 dBmFluctuations in reverse channel in headend. Typical value


Fluctuations in reverse channel in headend. Typical value

Power consumption < 1.5 W Typical value

RFOpticO

E

TP -20dB

FP 1310 nm optical transmitter module with OMI stabilization

ORTB F1310-SCA FP / BP 100G

BOOSTRAL 6610 / BETA 100G

vector.net 56

ORTB F1310-SCA FP UNIV FP 1310nm optical transmitter module with OMI stabilization

Parameter Value CommentLaser type FP IsolatedWavelength 1310 ± 40 nm

Output optical power 0 ± 0.5 dBmBandwidth 5 – 100 MHz

Minimal input level for NPR > 35dB - 8 dBμV/Hz

Measured in BETA PRO 60G node with reverse

channel redundancy, A3=A4=5dB, ingress switch = 0dB; noise BW=60MHz, optical

budget ~9dB @1310nm <�_�� =

Dynamic range for NPR > 35dB > 6 dB



budget ~9dB @1310nm <�_�� =

Optical connector type SC/APC J�)��@��

Alarm from reverse transmitter -3 dBm

Green - optical power > -3dBm; Red - optical

Power < -3dBm

Test point RF - directional - 20 dB Relative to RF signal feeding the laser diode

Stabilized optical power ± 0.5 dBm Fluctuations in reverse channel in headend

OMI change in temperature function ± 1 dB Fluctuations in reverse

channel in headendPower consumption < 1.5 W

RFOpticO

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TP -20dBFTB ATG

ORTB 3D1310-SCA UNIVDFB 1310nm optical transmitter module with OMI stabilization

Parameter Value CommentLaser type DFB IsolatedWavelength 1310 ± 20 nmOutput optical power 3 ± 0.5 dBmBandwidth 5 – 100 MHz




budget ~12dB @1310nm <�_�� =




budget ~12dB @1310nm <�_�� =

Optical connector type SC / APC J�)��@��


Green - optical power > -3dBm; Red - optical

Power < -3dBmTest point RF - directional - 20 dB Relative to RF signal

feeding the laser diode

RFOpticO

E

TP -20dBFTB ATG

DFB 1550nm optical transmitter module with OMI stabilization

ORTB 3D1550-SCA UNIV

Parameter Value CommentLaser type DFB Isolated

Wavelength 1550 ± 20 nm

Output optical power 3 ± 0.5 dBm

Bandwidth 5 – 100 MHz

Minimal input level for NPR > 35dB -5 dBμV/Hz



budget ~12dB @1550nm <�_�� =




budget ~12dB @1550nm <�_�� =


Alarm from reverse transmitter 0 dBm

Green - optical power > 0dBm

Red - optical Power < 0dBm




channel in headendPower consumption < 2 W

RFOpticO

E

TP -20dBFTB ATG

BETA PRO 60G

OFRBOptical receiver module

Parameter Value CommentWavelength 1100 – 1600 nm

Input optical power -5 – 2 dBm-8 – -1 dBm

OFRB LGOFRB HG

Bandwidth 47 – 1006 MHz%@��current ��_��jq�� typical, max. ��^


CNR 58 dB

Optical power input - 3 dBm,

4% OMI, input wavelength 1310nm, noise bandwidth

4.75MHz

Output level 72 ± 1 dBμV

"��7�?��~��J!9��wavelength 1310nm

��7^?��~��J!9��wavelength 1310nm

Responsivity Z��]_�j�}Z��j�}

@ 1310nm@ 1510nm

RFOpticO

E

ORTB F1310-SCA FP UNIV FP 1310nm optical transmitter module with OMI stabilization

Parameter Value Comment

Laser type FP Isolated

Wavelength 1310 ± 40 nm

Output optical power 0 ± 0.5 dBm

Bandwidth 5 – 100 MHz



channel redundancy, A3=A4=5dB, ingress

switch = 0dB; noise BW=60MHz, optical

budget ~9dB @1310nm <�_�� =



channel redundancy, A3=A4=5dB, ingress

switch = 0dB; noise BW=60MHz, optical

budget ~9dB @1310nm <�_�� =



Green - optical power > -3dBm

Red - optical Power < -3dBm




channel in headendPower consumption < 1.5 W

RFOpticO

E

TP -20dBFTB ATG

Plug-in ModulesFor BETA PRO 60G / GAMMA O33 / GAMMA U33

Plug

-in M

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channel in headendPower consumption < 2 W

vector.net 57

FP 1310nm optical transmitter module

ORT F1310-SCA FP ORT F1310-SCA / 42 FP ORT F1310-SCA / 30 FP


laser type FP non-isolated

Wavelength 1310 ± 40 nmOptical output power 0 ± 1 dBm?��+�)�ORT F1310-SCA FPORT F1310-SCA / 42 FPORT F1310-SCA / 30 FP

5 – 65 MHz5 – 42 MHz5 – 30 MHz

For internal RF input

Minimum input level for K��?�

ORT F1310-SCA FPORT F1310-SCA / 42 FPORT F1310-SCA / 30 FP

^�?¡��]�?¡��?¡��

RF signal feeding the laser diode @ 25°C, 5dB ��-��

60MHz load37MHz load25MHz load

Dynamic range for NPR > 30dB > 25 dB 5dB optical loss

Optical connector SC / APC J�)��@��Laser power status indicator - 3 dBm --

RF test point - directional - 15 dB Relative to RF signal feeding the laser diode

Insertion loss for internal RF input 5 dB For 0dB pad and OLP

module

Bandwidth 5 – 210 MHz For external RF input - port 1

Insertion loss for external RF input 4 dB For 0dB pad

OMI variation over temperature ± 2 dB

Optic RFO

E

REV PAD

TP -15dB

ExternalREV PAD

OE

ExternalRF input

OLP InternalRF input

5 - 210MHz

1310nm and CWDM optical transmitter scheme

for GAMMA O

Optic RFO

E

Parameter ValueCommentlaser type DFB isolatedWavelength 1310±20 nmJ��+��ORT 0D1310-SCAORT 3D1310-SCAORT 3D1310-SCA/42ORT 3D1310-SCA/30

0 ± 1 dBm3 ± 1 dBm3 ± 1 dBm3 ± 1 dBm

?��+�)�ORT 0D1310-SCAORT 3D1310-SCAORT 3D1310-SCA/42ORT 3D1310-SCA/30

5 – 65 MHz5 – 65 MHz5 – 42 MHz5 – 30 MHz

For internal RF input

Minimum input level for K��?�

ORT 0D1310-SCA ORT 3D1310-SCAORT 3D1310-SCA/42ORT 3D1310-SCA/30

0 ?¡��?¡��?¡��?¡��

RF signal feeding the laser diode @ 25°C, 5dB ��-��

60MHz load60MHz load37MHz load25MHz load


Optical connector SC / APC J�)��@��

Laser power status indicator 0 dBm


Red - optical power < 0dBm

RF test point - directional - 15 dB Relative to RF signal feeding the laser diode


module




Temperature range -40 – 55 °C Optical node ambient temperature

DFB 1310nm optical transmitter module

ORT 0D1310-SCA ORT 3D1310-SCA ORT 3D1310-SCA / 42ORT 3D1310-SCA / 30

FP 1310nm optical transmitter module with OMI sta-bilization

OFR 870-SCA OSR 870-SCA


Wavelength 1100 – 1600 nm

Optical input power range - 3 - 2 dBmBandwidth 47 – 870 MHz%@��current ��]��jq��


Optical power test point 1 ± 0.5 V/mW

RF level at the output of the module �]��_�?¡� 4.5% OMI/channel, 0dBm

input optical power

Optical Power Indicator - 5 dBm

Green - optical power > -5dBm

Red - optical power < -5dBm

RF test point - directional - 20 dB Relative to module output signal

Optic RFO

E

GAMMA O33, GAMMA U33

RFOpticO

E

TP -20dBFTB ATG

DFB CWDM optical transmitter module with OMI stabilizationXXXX = 1310, 1330, 1350, 1370, 1390, 1410, 1430, 1450, 1470, 1490, 1510, 1530, 1550, 1570, 1590, 1610

ORTB CXXXX-SCA UNIV

Parameter ValueComment

Laser type DFB isolated}��*�)�ORTB C1310-SCAORTB C1330-SCAORTB C1350-SCAORTB C1370-SCAORTB C1390-SCAORTB C1410-SCAORTB C1430-SCAORTB C1450-SCAORTB C1470-SCAORTB C1490-SCAORTB C1510-SCAORTB C1530-SCAORTB C1550-SCAORTB C1570-SCAORTB C1590-SCAORTB C1610-SCA

1310 ± 1, -2 nm1330 ± 1, -2 nm1350 ± 1, -2 nm1370 ± 1, -2 nm1390 ± 1, -2 nm1410 ± 1, -2 nm1430 ± 1, -2 nm1450 ± 1, -2 nm1470 ± 1, -2 nm1490 ± 1, -2 nm1510 ± 1, -2 nm1530 ± 1, -2 nm1550 ± 1, -2 nm1570 ± 1, -2 nm1590 ± 1, -2 nm1610 ± 1, -2 nm

16 wavelength, other on ��@��


Node operation temperature range - 25 – 50 ºC

Output optical power 3 ± 0.5 dBmBandwidth 5 – 100 MHz



channel redundancy, A3=A4=5dB, ingress switch

= 0dB; noise BW=60MHz, optical budget ~12dB

�__��<�_�� =



channel redundancy, A3=A4=5dB, ingress switch

= 0dB; noise BW=60MHz, optical budget ~12dB

�__��<�_�� =


Alarm from reverse transmitter 0 dBm


Red - optical power < 0dBm




channel in headend

Power consumption < 2 W

Plug

-in M

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Plug-in ModulesFor BETA PRO 60G / GAMMA O33 / GAMMA U33

vector.net 58

� � �� For 3-outputs optical node with dual reverse path. Allows redundant transmission while using redundant optical transmitter.

RCG 05

� � �� For 2-outputs optical node with dual reverse path. Allows redundant transmission while using redundant optical transmitte

RCG 06

� � �� For 1-output optical node with dual reverse path. Allows redundant transmission while using redundant optical tramsmiter.

RCG 07

Passive reverse moduleRP 600

� � �� ;��+��"� �� and equalizerGain controlled by 2-state interstage attenuator and indicated by LED

RA 65, RA 42, RA 30

Technical ParametersBandwidth 5 – 65 MHzInsertion loss ��_�?Level adjustment range 0 – 18 dBSlope adjustment range 0 – 10 dBTest point - directional 20 dB

TP

TP

DFB CWDM transmitter moduleXXXX = 1470, 1490, 1510, 1530, 1550, 1570, 1590, 1610nm

ORT DCXXXX-SCA

Parameter Value CommentLaser type DFB isolated

Wavelength ��7��

Optical output power 3 ± 1 dBm?��+�)�ORT DCXXXX-SCA 5 – 65 MHz For internal RF inputMinimum input level for NPR> 30dBORT DCXXXX-SCA ��?¡��

RF signal feeding the laser diode @ 25°C,

5dB passive optical loss, for 60MHz load



Laser power status indicator 0 dBm

Green - optical power > 0dBm; Red - optical

power < 0dBm

RF test point - directional - .15 dB Relative to RF signal feeding the laser diode


module





Node operation temperature range - 25 – 50 ºC

Optic RFO

E

Technical Parameters!�#��*��-��RAG 29-1RAG 29-2

1 x 29 ± 0.75 dB2 x 29 ± 0.75 dB

?��+�)�RAG 29-1, RAG 29-2RAG 29-1/42, RAG 29-2/42RAG 29-1/30

5 – 65 MHz5 – 42 MHz5 – 30 MHz

Flatness ± 0.7 dB

� � �� #�� +

RAG 29-2RAG 29-2 / 42

FP 1310nm optical transmitter module with OMI stabilization

RAG 29-1RAG 29-1 / 42 / 30

� � �� &��7�� 7��+�)��*��)��@�� of ports 2, 3 and 4.

RCG 01

� � �� For 3-outputs optical node with dual reverse path. ��@��-��~��*��as an independent reverse path.

RCG 02

� � �� For 2-outputs devices with single reverse path and for �7��+�)��)��@�� -��~��*��)�<-��7��=�

RCG 03

� � �� For 2-output optical node with single reverse path or dual ��)��~��*��)��<-��7��=�

RCG 04

Plug-in ModulesFor GAMMA O33 / GAMMA U33

Plug

-in M

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K��*��-��*�� ^K��-��^�!�� ?¡��_�!�� ]?¡��!�� ?¡��_!�� ?¡��

��7�^��?��7�^��?��7�^��?��7��^��?�

J��IMD3 = - 60dBc IMD2 = - 60dBc

110 dBμV102 dBμV

��+��RAG 29-1RAG 29-2

1.2 W2.4 W

vector.net 59

Type Frequency Range Attenuation

BF 15-65 T / RBPL 15-65 G

��_�!��]��7��!��300-1006 MHz -40dB /-40dB / -30dB

BF 15-85 T / RBPL 15-85 G

��_�!��]�7��!��300-1006 MHz -40dB /-40dB / -30dB

BF 15-204 T ��_�!��_]�7��!��300-1218 MHz -40dB /-40dB / -30dB

� � �� "��;��+�� BF XXX T / RBPL XX G


FTB 5 - 42 5 - 42MHz40dB for 53MHz < f < 545MHz

30dB for 545MHz < f < 755MHz10dB for 765MHz < f < 1006MHz

FTB 5 - 65 5 - 65MHz35dB for 80MHz < f < 460MHz

20dB for 460MHz < f < 600MHz8dB for 600MHz < f < 1006MHz

FTB 5 - 85 5 - 85MHz35dB for 105MHz < f < 560MHz20dB for 560MHz < f < 710MHz

10dB for 710MHz < f < 1006MHz

Type Frequency RangeOLP 65 5 – 65MHzOLP 42 5 – 42MHzOLP 30 5 – 30MHz

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Input/Output splitter moduleISG 65

Automatic gain control module controlled by optical power at the input of receiver

OPTICAL AGC 000-X

Automatic gain control module controlled by pilot tone

RF AGC XXX-X

State Attenuation

0dB 0.5dB

6dB 6dB ± 0.5

OFF > 30dB

Technical Parameters ��+�)�AGC 000-6AGC 000-3

85 – 862 MHz47 – 862 MHz

Control range 8 dBAGC insertion loss 3.5 – 11 dBStability over ± 2dBm input optical power change ± 1 dB

Technical Parameters?��+�)�AGC 543-6AGC 439-6

5 – 65 MHz5 – 65 MHz

Control Range 8 dB��-��@��(��ªAGC 543-6AGC 439-6

543.25 MHz439.25 MHz

Output Level Stability ± 1 dBInsertion Loss 3 – 11 dBOperating Temperature Range -40 – 60 °C

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!�� :�� DF XXX T / DF

'��;��++��+%�� HF XXX T / HPB XX G

Type Upstream Frequency Range

Downstream Frequency Range

DF 65-85 T 5 – 65 MHz 85 – 1218 MHzDF 85-110 T 5 – 85 MHz 105 – 1218 MHzDF 204-258 T 5 – 204 MHz 258 – 1218 MHzDF 65A 5 – 65 MHz 85 – 862 MHzDF 55A 5 – 55 MHz 75 – 862 MHzDF 42A 5 – 42 MHz 54 –�]^��DF 30A 5 – 30 MHz 47 –�]^��DF 85G 5 – 85 MHz 104 –��^�!��ªDF 65G 5 – 65 MHz 85 – 1006 MHzDF 42G 5 – 42 MHz 54 –��^��

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FILTERS


HF 85 T/HPB 85G ��^_�!��Z�]_�!�� Z��_�?��_�?HF 110T/HPB 110G ��]_�!��Z��!�� Z��_�?��_�?

HF 258 T ��!��Z��_]�!�� Z��_�?��_�?

HPB 54G ��~��_~�� Z��_�?��_�?


RHP 15 ��_�� Z��_?��?

RHP 25 ��_�� Z��_?��?

� � �� +�� RHP

Type Frequency Range AttenuationLF 65 T / LPBL 65 G ��^_��]_�� Z��?��~�?LF 85 T / LPBL 85 G ��]_�� Z��?��~�?LF 204 T ��_]�� Z��?��~�?LPB 42G ��~��_~�� Z��?��~�?

� � �� +��;%�� LF XXX T / LPBL XX G


RBP 15 - 42 RBP 15 - 65 RBP 15 - 85

15 - 42 MHz 15 - 65 MHz 15 - 85 MHz

25dB for f < 10MHz 23 dB for 85MHz < f < 540MHz

15 dB for 540MHz < f < 862MHz 10 dB for 862MHz < f < 1006MHz

RBP 5 - 42 RBP 5 - 65 RBP 5 - 85

5 - 42 MHz 5 - 65 MHz 5 - 85 MHz

25 dB for f < 2MHz 15 dB for 100 MHz < f < 660 MHz

10 dB for 660 MHz < f < 1006 MHz

� � �� "��;��+�� RBP

� � �� ;��+�: �� and equalizerGain controlled by 2-state interstage attenuator and indicated by LED

RA 65Z, RA 42Z RA 65Z / 30

Technical Parameters?��+�)�RA 65, RA 65Z, RA 65Z / 30 RA 42, RA 42ZRA 30

5 – 65 MHz5 – 42 MHz5 – 30 MHz

Gain�RA 65, RA 65Z RA 42, RA 42Z, RA 30RA 65Z / 30

25/20 dB25/20 dB30/25 dB

K��*�� ~�?Level adjustment range 0 – 20 dBSlope adjustment range 0 – 10 dBTest point - directional - 20 dBNPR for�60MHz @ 26dB V/Hz50MHz @ 27dB V/Hz37MHz @ 28dB V/Hz25MHz @ 29dB V/Hz

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J��IMD 3 = - 60dBc IMD 3 = - 60dBc

115 dBμV103 dBμV

Power consumption 1.5 W

TP

Plug-in ModulesFilters / Attenuators & Equalizers / Taps

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SP 4 T TO 804 / TO 1004 / LTO 1004

Type Frequency Range EqualizationEQ 8XX 47 –�]^�� 1 – 24 dB, step 1 dBEQ 6XX 47 –�^�^�� 3, 6, 9, 12 dBEQ 4XX 47 –�~_�� 3, 6, 9, 12, 15 dB

Reverse equalizerEQ XXX T / LREQ XX G

Type Frequency RangeEQ 65 T / LREQ 65 G 5 –�^_��EQ 85 T / LREQ 85 G 5 –�]_��EQ 200 T 5 –��REQ 55 5 –�__��REQ 42 5 –�~��

Fixed attenuator moduleAT XX T / AT / ATG / MINI ATG

Type Frequency Range AttenuationAT XX T/ ATG 10XX 5 –��]�� 1 - 20 dB, 1 dB stepAT 8XX 5 –�]^�� 1 – 21dB, step 1dBATG 8XX 5 –��^�� 0 – 25dB, step 1dBMini ATG 10XX 5 –��^�� 0 – 20dB, step 1dB

Cable simulator moduleCS

Input variable equalizer moduleEV

Type Frequency Range Equalization

EV 818 47 -�]^�� 0 - 18 dB

EV 618 47 -�^�^�� 0 - 18 dB

EV 418 47 -�~_�� 0 - 18 dB

Type Frequency Range Attenuation at upper frequency

CS 1218 3 T 47 -��]�� 3.5 dB

CS 1218 6 T 47 -��]�� 6.5 dB

CS 1218 9 T 47 -��]�� 9.5 dBCS 80X 47 -�]^�� 3 or 6 dBCS 60X 47 -�^�^�� 3 or 6 dBCS 1035 47 -��^�� 3.5 dBCS 1065 47 -��^�� 6.5 dB

Reverse jumper module

Jumper module

JP 0 T, JP 0 T2 AT 800 / AT 1000 /

ATG 0 / ATL 1000

RJP

Input variable attenuator moduleAV

Type Frequency Range AttenuationAV 818 47 –�]^�� 0 – 18dB

USB-RJ11 HARNESS

Parameter Description Min. Typical Max.VCC Output Power Voltage 4.25 V 5.0 V 5.25 VIO Output Power Current - - 75 mA T Operating Temperature Range - 40 °C - 85 °C

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TTL-232R-5V Electrical Parameters

ª Monitornig kit with HCM, DCM or EDCM transponder

Extension to monitoring functionalityGAMMA O8X-33A-AF Monitoring Kit MKGO33GAMMA O8M-33A-AF Monitoring Kit MKGO33HARGON 2710 / BP30G 089Y !��*�«��!«?��ªHARGON 2730 / BP33G 089Y !��*�«��!«?��ªHARGON 2730 / BP33G 089M !��*�«��!«?��ªHARGON 2610 / BP20G 089Y !��*�«��!«?��ªHARGON 2630 / BP23G 089Y !��*�«��!«?��ªHARGON 2630 / BP23G 089M !��*�«��!«?��ªGAMMA U8X-33A-AF Monitoring Kit MKGU33GAMMA M8X-33A-AF Monitoring Kit MKGU33

Input tap module / output tap module

TO XX T / TI XX T / TI / TO / LTI / LTO

Type Frequency Range

Attenuation input to BY-PASS / atte-nuation to OUT1

Attenuation input �� Q�� %nuation to OUT2

TO 6 T 5-1218 MHz 4.2 dB 6.3 dB

TO 8 T 5-1218 MHz 2.5 dB 8.0 dB

TO 10 T 5-1218 MHz 2.2 dB 10.2 dB

TO 13 T 5-1218 MHz 2.2 dB 13.0 dB

TO 10 T 5-1218 MHz 1.5 dB 15.0 dB

TO 17 T 5-1218 MHz 1.5 dB 17.0 dB

TI 6 T 5-1218 MHz 6.0 dB 4.0 dB

TI 8 T 5-1218 MHz 8.0 dB 2.2 dB

TI 10 T 5-1218 MHz 10.0 dB 2.0 dBTI 13 T 5-1218 MHz 13.0 dB 2.0 dB

TI 15 T 5-1218 MHz 15.0 dB 1.5 dB

TI 17 T 5-1218 MHz 17.0 dB 1.5 dB

TI / TO 808 47 - 862 MHz 2.2 dB 7.9 dBTI / TO 810 47 - 862 MHz 2.7 dB 9.7 dBTI / TO 813 47 - 862 MHz 1.7 dB 13.1 dBTI / TO 815 47 - 862 MHz 1.1 dB 14.8 dBTI / TO 817 47 - 862 MHz 0.9 dB 16.9 dBTO 1008 47 - 1006 MHz 2.0 dB 8.5 dBTO 1010 47 - 1006 MHz 2.2 dB 9.8 dBTO 1013 47 - 1006 MHz 1.45 dB 13.4 dBTO 1015 47 - 1006 MHz 1.7 dB 16.0 dBTO 1017 47 - 1006 MHz 1.7 dB 17.0 dBLTI / LTO 1008 47 - 1006 MHz 2.0 dB 8.0 dBLTI / LTO 1010 47 - 1006 MHz 2.0 dB 10.0 dBLTI / LTO 1013 47 -1006 MHz 1.5 dB 13.0 dBLTI / LTO 1015 47 - 1006 MHz 1.0 dB 15.0 dBLTI / LTO 1017 47 - 1006 MHz 1.0 dB 17.0 dB

Contains Monitoring Module (DCM / EDCM or HCM) and Mounting Kit

MONITORING KIT

K�� : � |�� EQ

ATTENUATORS & EQUALIZERS / TAPS

Type Frequency Range Attenuation Equalization

AQ 810-06 47 –�]^�� 10 dB 6 dB

AQ 810-09 47 –�]^�� 10 dB 9 dBAQ 806-06 47 –�]^�� 6 dB 6 dBAQ 806-09 47 – 862 MHz 6 dB 9 dB

K�� : �� |�� AQ

Type Frequency RangeEQ 1006 ET 47 - 1006 MHzEQ 1218 ET 47 - 1218 MHz

EQ XXX ET Forward equalizer

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Plug-in ModulesAttenuators & Equalizers / Taps

USB to RJ11 cable with 5V TTL level is used to direct communication between CMS platform and device deployed in the network. ��)��)�� (�� (��%'�J��employees to optimize the voltage levels to proper communication.

VECTOR Krzemowa 6 81-577 Gdynia, PolandTel.: +48 58 77 17 000 Fax: +48 58 77 17 [email protected]

www.vector.net

Documents

Product Catalogue - VECTOR 751 Optical FTTB ... Network throughput comparable to EPON/GPON ... Increased RF spectrum in both downstream and upstream > ? - ˛% @