ALFOPlus80HDX v01.06.00 - r3 [PDF]

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ALFOplus80HDX Access Link Full Outdoor 80 GHz (E-Band digital radio system) Adaptative Code Modulation and Bandwidth ACMB Multi Band Link and XPIC configuration Native IP - Point to Point radio link

Copyright Siae Microelettronica S.p.a. The data contained in this document should not be disclosed or published by third parties

Training items 1. 2. 3. 4. 5. 6. 7.

General overview ALFOplus80HDX Installation ODU Software connection Line up Ethernet switch Maintenance Alarm & Troubleshooting

ALFOplus80HDX Connectors LAN3 (Gi 0/6) RJ45 with PoE (Traffic and/or Management port)

LAN4 (Gi 0/1) RJ45 with PoE Status LED

(Traffic and/or Management port)

Connectors not used must be protected with the proper cap

48V port

MNGT(Gi 0/7)

DC power connector and console

Local Management connector and pointing alignment

PHY1

XPIC connector

PHY2

No PoE Connector

(Traffic and/or Management port)

Versions available :

(Traffic and/or Management port)

Siae Code

Description ALFOplus80HDX

RF/Subband

GB9920

PHY1 SFP+ PHY2 SFP+ LAN3 RJ45 with PoE LAN4 RJ45 with PoE

1L

GB9921

PHY1 SFP+ PHY2 SFP+ LAN3 RJ45 with PoE LAN4 RJ45 with PoE

1H

GB9920-01

PHY1 SFP+ PHY2 SFP+ LAN3 RJ45 with PoE LAN4 RJ45 with PoE

1L

GB9921-01

PHY1 SFP+ PHY2 SFP+ LAN3 RJ45 with PoE LAN4 RJ45 with PoE

1H

1000BaseT SFP modules not supported

They improve the Max RSL threshold without distortions and damage NEW FW 1.2.0

Block Diagram Radio ALFOplus80HDX ODU ALFOplus80HDX

RFCOH

IP Ethernet Traffic :

Base Band

Physical interface 1

10Giga Mode

Physical interface 2 LAN3 10/100/1000BaseT

Gi 0/6

LAN2 Gi 0/3 1Gbps/2.5Gbps

LAN4 10/100/1000BaseT

Gi 0/1

XGLAN 10Gbps Ex 0/1 LAN1 1/2.5Gbps

Switch Ethernet

Management Traffic : MNGT 10/100BaseT

Ex 0/2 Gi 0/7

DC/DC

Led Alarm XPIC

115.2Kbps

TRX 10Gbps

Mod Radio Layer 1 RLAG

TX

Modem

10Gbps Demod

RX RF

To the Remote Site

VLAN interface

CPU 48V ( Console RS232, 48Vdc )

Ip Ethernet

IP Agent

RFCOH( Radio Frame Complementary Over Head) transport information of : -Alingment (new frame) -LLI (Local Link ID) 8bit -etc.

80HDX Cables

48V port

Remove it after use

MNGT port

Console RS232 (115.2kbps 8-N-1-N )

F03667 (already assembled)

F03622 (already assembled) Siae Code

View

P04185

M10154

2x0.75mmq for d ≤ 100m M10166

2x1.5mmq for d ≤ 200m

RJ45 100BaseT

48V port

Console Cable Console RS232 (115.2kbps 8-N-1-N )

outside view

F03622 Inside view

Remove it after use

Pinout

Description

1

Vdc (-) = -48 Volt

2

Vdc (+) = 0 Volt

3

Rx_Console

4

Tx_Console

5

GND_Console

Shield

Ground

MNGT Cable

MNGT port

Remove it after use outside view

Rx TRx A Vagc [V]

3 2.25 1.5 0.75 Inside view 0

Permanent Damage

RSSI for FW ≥ 01.02.00

F03667

-80 -65 -45 -25 -5 +3 PRx [dBm] M12 Pinout

Description

RJ45 Pinout

1

TXP

1

2

RXP

3

3

TXN

2

4

RXN

6

5

Vpointing ( + )

n.c.

Shield

Vpointing ( - )

n.c.

RJ45 100BaseT

NEW FW 1.2.0

Rosenberger

RJ45 Disconnection The release of the plug from the RJ45 receptacle can be performed by finger or by non metallic tool. The use of screwdrivers or equivalent tool can damage the receptacle and the board where is soldered to

3 2 1

1

2

4

J24304 – RJ45 ejector tool (optional)

1) unscrew and unhook the Rosenberger cylinder 2) unlock by pushing Rosenberger clamp 3) push the latching tab of the RJ45 connector to unlock it 4) the ethernet cable can be extracted from the unit with a linear movement

ALFOplus80HDX 1+0 Remote Radio

Local Radio

Frequency channel 1

RJ45

10Gbps SFP+

L 10Gbps 2000MHz@128QAM 5.8Gbps 1000MHz@256QAM 4.5Gbps 750MHz@256QAM 2.9Gbps 500MHz@256QAM 1.4Gbps 250MHz@256QAM

LAN3 LAN4

PHY1

LAN3 LAN4

H PHY1

RJ45

10Gbps SFP+ 10Giga Mode: Enabled

Physical interface 1 Physical interface 2 (Not connected to the switch)

1+0 = 1 unprotected radio link 1 frequency channel 1 polarization ODU tx active - rx active 10 Giga mode : Enable Port Protection (EPP) : Disabled

LAN3 1Gbps

LAN2 Gi 0/3 1Gbps/2.5Gbps Gi 0/6

LAN4 1Gbps

XGLAN 10Gbps Ex 0/1 LAN1 1/2.5Gbps

Gi 0/1

Switch Ethernet

Ex 0/2

TRX 10Gbps

Layer 1 RLAG

To Radio

NEW FW 1.1.0

ALFOplus80HDX 1+0 Remote Radio

Local Radio

Frequency channel 1 L

H PHY1

PHY 2

2x10Gbps SFP+

10Gbps 2000MHz@128QAM 5.8Gbps 1000MHz@256QAM 4.5Gbps 750MHz@256QAM 2.9Gbps 500MHz@256QAM 1.4Gbps 250MHz@256QAM

SWITCH

PHY1

PHY 2

2x10Gbps SFP+ SWITCH Port Protection (EPP)

Physical interface 1 Physical interface 2

1+0 = 1 unprotected radio link 1 frequency channel 1 polarization ODU tx active - rx active 10 Giga mode : Enable Port Protection (EPP) : Enabled – managed by ODUs

LAN2 Gi 0/3 1Gbps/2.5Gbps XGLAN 10Gbps Ex 0/1

Switch Ethernet

Ex 0/2

TRX 10Gbps

Layer 1 RLAG

To Radio

NEW FW 1.1.0

ALFOplus80HDX 1+0 Remote Radio

Frequency channel 1

Local Radio H 4x1Gbps or 2x2.5Gbps SFP SWITCH

L 4Gbps 4x1Gbps or 2x2.5Gbps SFP Enable LLF bidirectional

LAG protocol

SWITCH LAG protocol 10Giga Mode: Disable

Physical interface 1 Physical interface 2

1+0 = 1 unprotected radio link 1 frequency channel 1 polarization ODU tx active - rx active 10 Giga mode : Disable

LAN3 1Gbps

Gi 0/6

LAN4 1Gbps

LAN2 Gi 0/3 1Gbps/2.5Gbps Ex 0/1 LAN1 1/2.5Gbps

Gi 0/1

Switch Ethernet

Ex 0/2

TRX 10Gbps

Layer 1 RLAG

To Radio

NEW FW 1.1.0

ALFOplus80HDX 1+0 Remote Radio

Frequency channel 1

Local Radio

SFP RJ45

L 10Gbps 2000MHz@128QAM 5.8Gbps 1000MHz@256QAM 4.5Gbps 750MHz@256QAM 2.9Gbps 500MHz@256QAM 1.4Gbps 250MHz@256QAM

PHY1 PHY2 LAN3 LAN4

PHY1 PHY2 LAN3 LAN4

H

SFP RJ45

10Gbps SFP+

10Gbps SFP+ 10Giga Mode: Mixed

Physical interface 1 Physical interface 2

1+0 = 1 unprotected radio link 1 frequency channel 1 polarization ODU tx active - rx active 10 Giga mode : Mixed

LAN3 1Gbps

Gi 0/6

LAN4 1Gbps

LAN2 Gi 0/3 1Gbps/2.5Gbps Ex 0/1 XGLAN 10Gbps

Gi 0/1

Switch Ethernet

Ex 0/2

TRX 10Gbps

Layer 1 RLAG

To Radio

NEW FW 1.4.0

ALFOplus80HDX 1+0 Remote Radio

Frequency channel 1

Local Radio

RJ45

L 10Gbps 2000MHz@128QAM 5.8Gbps 1000MHz@256QAM 4.5Gbps 750MHz@256QAM 2.9Gbps 500MHz@256QAM 1.4Gbps 250MHz@256QAM

2 x 10Gbps SFP+

PHY1 PHY2 LAN3 LAN4

PHY1 PHY2 LAN3 LAN4

H

RJ45

2 x 10Gbps SFP+ SFP+ Physical interface 1

10Giga Mode: Enable Dual

SFP+ Physical interface 2

1+0 = 1 unprotected radio link 1 frequency channel 1 polarization ODU tx active - rx active 10 Giga mode : Enable Dual

LAN3 1Gbps

Gi 0/6

LAN4 1Gbps

Buffer

LAN2 Gi 0/3 1Gbps/2.5Gbps Ex 0/1 XGLAN 10Gbps

Gi 0/1

Switch Ethernet

Ex 0/2

TRX 10Gbps

Layer 1 To RLAG Radio

NEW FW 1.6.0

ALFOplus80HDX 2+0 ACAP Local Radio Vertical

Horizontal

PHY1

PHY 2 LAN3 LAN4/Mngt XPIC

XPIC LAN4/Mngt LAN3 PHY 2 PHY1

ODUA

H

H

Antenna Orthomode

Coupler Orthomode

Freq. Ch. 1 Freq. Ch. 2

ODUA

L

PHY 2 LAN3 LAN4/Mngt XPIC

L

XPIC LAN4/Mngt LAN3 PHY 2 PHY1

20Gbps ODUB

2x2000MHz@128QAM

Remote Radio

PHY1

Vertical

Horizontal

ODUB

Enable LLF bidirectional Using External LAG protocol

Using External LAG protocol

= active link = EPP link

1 Link in 2+0 FD 2 frequency channel 2 polarizations 10 Giga mode : Enable Aggregation/Carrier : Disable ODUA f1(v) tx active - rx active ODUB f2(h) tx active - rx active

V

H

ACAP = Adjcent Channel Altenate Polarisation

ACAP NEW FW 1.1.0

ALFOplus80HDX 2+0 ACAP Local Radio Vertical

Aggregator-Preferential PHY 1 PHY 2 LAN3 LAN4 or Mngt XPIC

XPIC LAN4 or Mngt LAN3 PHY 2

Horizontal

H

H

PHY 1

Antenna Orthomode

2x1Gbps with PoE

ROUTER

Coupler Orthomode

Freq. Ch. 1 Freq. Ch. 2 10Gbps

L

L

2x2000MHz@128QAM

Carrier-Preferential 2x10Gbps

Aggregator-Preferential

Remote Radio

PHY 1 PHY 2 LAN3 LAN4 or Mngt XPIC

XPIC LAN4 or Mngt LAN3 PHY 2

Vertical

Horizontal

PHY 1

Carrier-Preferential

= active link 2x1Gbps with PoE 2x10Gbps = passive link = Data/Inband 10Gbps ROUTER = PLA F15479 MM or F15484 SM V = Mngt traffic M02472 L=2m = Out Of Band (alternative to inband)

1 Link in 2+0 FD 2 frequency channel 2 polarizations 10 Giga mode : Enable Aggregation/Carrier : ODU f1(v) : Aggregator (Preferential) over Physical Interface 2 ODU f2(h) : Carrier (Preferential) over Physical Interface 2

H

ACAP = Adjcent Channel Altenate Polarisation

ACAP

NEW FW 1.2.0

ALFOplus80HDX 2+0 XPIC Local Radio Vertical

PHY 1 PHY 2 LAN3 LAN4 or Mngt XPIC

XPIC LAN4 or Mngt LAN3 PHY 2

Horizontal

H

Antenna Orthomode

H

10Gbps 1000MHz@256QAM 8.5Gbps 750MHz@256QAM 5.5Gbps 500MHz@256QAM 2.6Gbps 250MHz@256QAM

Carrier-Preferential 2x1Gbps with PoE

ROUTER

Coupler Orthomode

L

10Gbps

PHY 1

2x10Gbps

Aggregator-Preferential

Aggregator-Preferential

L

Remote Radio

PHY 1 PHY 2 LAN3 LAN4 or Mngt XPIC

XPIC LAN4 or Mngt LAN3 PHY 2

Vertical

Horizontal

PHY 1

Carrier-Preferential

= active link 2x1Gbps with PoE 2x10Gbps = passive link = Data/Inband 10Gbps ROUTER = PLA F15479 MM or F15484 SM V = Mngt traffic M02472 L=2m = Out Of Band (alternative to inband) = Xpic cable F03696

1 Link in 2+0 XPIC 1 frequency channel 2 polarizations H SynchE is mandatory 10 Giga mode : Enable Aggregation/Carrier : CCDP = Co Channel Dual Polarized ODU V : Aggregator (Preferential) over Physical Interface 2 CCDP ODU H : Carrier (Preferential) over Physical Interface 2

NEW FW 1.2.0

Initial Condition 2+0 XPIC = 10Gbps Data + InBand + SyncE = Line Protection enabled = PLA Radio = Management traffic = SyncE

PHY2 SFP+ 10G

LAN1 P:1

FPGA

PHY1 SFP+ 10G

80HDX (Aggregator-Pref.) TRX

TRX P:1

SETS LAN2 P:2

LAN2 P:2

Mod XGLAN

MGT

PLA Radio

TRX

Ethernet Switch

Dem

Mod PLA Radio

Dem

TRX

Ethernet Switch

FPGA

LAN1 P:1

MGT

XPIC

TRX

TRX P:1

FPGA

SETS

LAN2 P:2

Mod TRX

Ethernet Switch

LAN1

SETS

LAN2 P:2

XGLAN OUT OF BAND MGT

LAN4

OUT OF BAND

LAN3 LAN4

PHY2 SFP+ 10G LAN3

FPGA XPIC

PHY2 SFP+ 10G

PHY1 SFP+ 10G

XGLAN

OUT OF BAND

PHY1 SFP+ 10G

DATA+INBAND+SyncE

LAN1

SETS

LAN3 LAN4

80HDX (Aggregator-Pref.)

PLA Radio

FPGA

80HDX (Carrier-Pref.)

Dem

FPGA

DATA+INBAND+SyncE

REMOTE SITE

FPGA

LOCAL SITE

Mod Dem

PHY1 SFP+ 10G PHY2 SFP+ 10G LAN3

PLA Radio

FPGA

XGLAN TRX

Ethernet Switch

80HDX (Carrier-Pref.)

LAN4 MGT

OUT OF BAND

NEW FW 1.2.0

LINE FAILURE “switch-over" in case of Loss of Signal (XGLAN or MNGT or LAN4). LOS generated by the line interfaces in case of switchover

LOCAL SITE

FAILURE 80HDX (Aggregator-Pref.) Carrier PHY2 SFP+ 10G

LAN1 P:1

FPGA

PHY1 SFP+ 10G

TRX P:1

SETS LAN2 P:2

LAN2 P:2

Mod

MGT

PLA Radio

TRX

Ethernet Switch

Dem

DATA+INBAND+SyncE

LAN1

SETS

XGLAN

LOS

80HDX (Aggregator-Pref.)

TRX

LAN3 LAN4

REMOTE SITE

FPGA

LOS

= 10Gbps Data + InBand + SyncE = Line Protection enabled = PLA Radio = Management traffic = SyncE

Mod

PHY1 SFP+ 10G PHY2 SFP+ 10G LAN3

XGLAN

PLA Radio

Dem

FPGA

TRX

Ethernet Switch

FPGA

LAN4 MGT

OUT OF BAND TRX P:1

SETS LAN2 P:2

LAN2 P:2

Mod XGLAN

OUT OF BAND MGT

TRX

Ethernet Switch

LAN1

SETS

LAN3 LAN4

XPIC

TRX

PLA Radio

Dem

FPGA

80HDX (Carrier-Pref.) Aggregator

FPGA

PHY2 SFP+ 10G

XPIC LAN1 P:1

FPGA

DATA+INBAND+SyncE PHY1 SFP+ 10G

Mod Dem

PHY1 SFP+ 10G PHY2 SFP+ 10G LAN3

PLA Radio

FPGA

XGLAN TRX

Ethernet Switch

80HDX (Carrier-Pref.)

LAN4 MGT

OUT OF BAND

NEW FW 1.2.0

HW FAILURE / POWER DOWN “switch-over" in case of Aggregator HW Failure/power off

= 10Gbps Data + InBand + SyncE = Line Protection enabled = PLA Radio = Management traffic = SyncE

80HDX (Aggregator-Pref.) Carrier

PHY2 SFP+ 10G

LAN1 P:1

FPGA

PHY1 SFP+ 10G

TRX

FAILURE

TRX P:1

LAN2 P:2

LAN2 P:2

Mod PLA Radio

TRX

Ethernet Switch

Dem

DATA+INBAND+SyncE

LAN1

SETS

XGLAN

MGT

80HDX (Aggregator-Pref.)

SETS

LAN3 LAN4

REMOTE SITE

FPGA

LOCAL SITE

Mod

PHY1 SFP+ 10G PHY2 SFP+ 10G LAN3

XGLAN

PLA Radio

Dem

FPGA

TRX

Ethernet Switch

FPGA

LAN4 MGT

OUT OF BAND TRX P:1

SETS LAN2 P:2

LAN2 P:2

Mod XGLAN

OUT OF BAND MGT

TRX

Ethernet Switch

LAN1

SETS

LAN3 LAN4

XPIC

TRX

PLA Radio

Dem

FPGA

80HDX (Carrier-Pref.) Aggregator

FPGA

PHY2 SFP+ 10G

XPIC LAN1 P:1

FPGA

DATA+INBAND+SyncE PHY1 SFP+ 10G

Mod Dem

PHY1 SFP+ 10G PHY2 SFP+ 10G LAN3

PLA Radio

FPGA

XGLAN TRX

Ethernet Switch

80HDX (Carrier-Pref.)

LAN4 MGT

OUT OF BAND

NEW FW 1.2.0

Aggregator Link Failure In case of alarm on the Aggregator : demod Fail or TRX LOS or TX Fail or remote demod fail

= 10Gbps Data + InBand + SyncE = Line Protection enabled = PLA Radio = Management traffic = SyncE

PHY2 SFP+ 10G

LAN1 P:1

FPGA

PHY1 SFP+ 10G

80HDX (Aggregator-Pref.) TRX

TRX P:1

SETS LAN2 P:2

Mod XGLAN

MGT

PLA Radio

TRX

Ethernet Switch

Dem

LAN2 P:2

Mod PLA Radio

Dem

TRX

Ethernet Switch

FPGA

LAN1 P:1

MGT

XPIC

TRX

TRX P:1

FPGA

SETS

LAN2 P:2

Mod TRX

Ethernet Switch

LAN1

SETS

LAN2 P:2

XGLAN OUT OF BAND MGT

LAN4

OUT OF BAND

LAN3 LAN4

PHY2 SFP+ 10G LAN3

FPGA XPIC

PHY2 SFP+ 10G

PHY1 SFP+ 10G

XGLAN

OUT OF BAND

PHY1 SFP+ 10G

DATA+INBAND+SyncE

LAN1

SETS

FAILURE

LAN3 LAN4

80HDX (Aggregator-Pref.)

PLA Radio

FPGA

80HDX (Carrier-Pref.)

Dem

FPGA

DATA+INBAND+SyncE

REMOTE SITE

FPGA

LOCAL SITE

Mod Dem

PHY1 SFP+ 10G PHY2 SFP+ 10G LAN3

PLA Radio

FPGA

XGLAN TRX

Ethernet Switch

80HDX (Carrier-Pref.)

LAN4 MGT

OUT OF BAND

NEW FW 1.2.0

Carrier Link Failure In case of alarm on the Carrier : demod Fail or TRX LOS or TX Fail or remote demod fail or LAN2 LOS or HW Failure/power off

= 10Gbps Data + InBand + SyncE = Line Protection enabled = PLA Radio = Management traffic = SyncE

PHY2 SFP+ 10G

LAN1 P:1

FPGA

PHY1 SFP+ 10G

80HDX (Aggregator-Pref.) TRX

TRX P:1

SETS LAN2 P:2

LAN2 P:2

Mod XGLAN

MGT

PLA Radio

TRX

Ethernet Switch

Dem

Mod PLA Radio

Dem

TRX

Ethernet Switch

FPGA

LAN1 P:1

MGT

TRX P:1

SETS

FPGA

XPIC

TRX

Mod TRX

Ethernet Switch

PLA Radio

FPGA

80HDX (Carrier-Pref.)

Dem

LAN1

SETS

FAILURE

LAN2 P:2

XGLAN OUT OF BAND MGT

LAN4

OUT OF BAND

LAN3 LAN4

PHY2 SFP+ 10G LAN3

FPGA XPIC

PHY2 SFP+ 10G

PHY1 SFP+ 10G

XGLAN

OUT OF BAND

PHY1 SFP+ 10G

DATA+INBAND+SyncE

LAN1

SETS

LAN3 LAN4

80HDX (Aggregator-Pref.)

LAN2 P:2

FPGA

DATA+INBAND+SyncE

REMOTE SITE

FPGA

LOCAL SITE

Mod Dem

PHY1 SFP+ 10G PHY2 SFP+ 10G LAN3

PLA Radio

FPGA

XGLAN TRX

Ethernet Switch

80HDX (Carrier-Pref.)

LAN4 MGT

OUT OF BAND

NEW FW 1.2.0

MBL 80HDX & ALFOplus2 Physical Link Aggregation Management Out Of Band

DATA + INBAND

Local site

10Gbps

ALFO+80HDX Aggregator PHY1 PHY2 LAN3 LAN4 XPIC

2x1Gbps with PoE

ROUTER

H

L RLAG 10Gbps

ALFO+2 Carrier

up to 2Gbps

H

Remote site

PHY1 PHY2 LAN3 LAN4 XPIC

up to 10Gbps

ALFO+2 Carrier LAN1 LAN2 LAN3 LAN4 MNGT

ALFO+80HDX Aggregator

L

= active link = passive link = Data/Inband 10Gbps = PLA connection 2.5Gbps = Mngt traffic M02472 L=2m = Out Of Band (alternative to inband)

LAN1 LAN2 LAN3 LAN4 MNGT 2x1Gbps with PoE

10Gbps

ROUTER

1Link in Multiband 1+0 with 80HDX ETH RLAG L1 on Radio and PHY2 ports of 80HDX 10 Giga mode : Mixed Aggregation/Carrier : HPLA Aggregator over Physical Interface 2 1+0 or 2+0 FD or 2+0 XPIC with ALFO+2 80HDX FW 1.3.0 & AP2 FW 1.6.1

MBL 80HDX & ALFOplus2 = 10Gbps data traffic = HPLA Radio Aggregation = Management traffic = SyncE

LOCAL SITE TRX

TRX P:1

SETS

SETS LAN2 P:2

Mod

LAN3 XGLAN LAN4 MGT

Ethernet Switch

SETS FPGA

LAN1 LAN2 SFP 2.5G

Dem

FPGA

PLA Radio

TRXA P:1 TRXB P:2

Mod

Mod

Dem

Dem

TRX

Ethernet Switch

Mod

Mod

FPGA

ALFOplus2 Carrier

Dem

PHY2 SFP 2.5G

XGLAN TRX

Ethernet Switch

SETS

PLA Radio

LAN4 MGT

LAN1 LAN2 SFP 2.5G LAN3

LAN2 TRX

FPGA Dem

DATA+INBAND PHY1 SFP+ 10G

LAN3

FPGA

TRXA TRXB

PLA Radio

LAN2

MGT

Dem

Mod

LAN2 P:1

LAN3 LAN4

PLA Radio

TRX

FPGA

LAN1 P:1

ALFOplus80HDX Aggregator

FPGA

PHY2 SFP 2.5G

ALFOplus80HDX Aggregator FPGA

DATA+INBAND PHY1 SFP+ 10G

REMOTE SITE

Ethernet Switch

LAN4 MGT

ALFOplus2 Carrier 80HDX FW 1.3.0 & AP2 FW 1.6.1

Single Antenna Multiband OMT coupler

(Only For 15/18/23GHz)

MBL AGS20L & 80HDX ODU

ODU 80HDX PHY1 Carrier PHY2

PHY1 80HDX PHY2 Carrier LAN3 LAN4

H

up to 10Gbps

XPIC Hybrid PLA (fiber)

Only Orthomode Local ODU Mngt ASNK-52 Coupler

H

10G SFP+

PSU1 (slot9)

FAN (slot10/12)

PSU2 (slot11)

AGS20L

1G SFP

RIM (slot7)

DRI (slot8)

CTL2 (slot5)

LIM (slot6)

RIM /DRI (slot3)

RIM /DRI (slot4)

CTL1 (slot1)

LIM (slot2)

L

H

LAN4 XPIC

Orthomode Coupler

Only Local Mngt

Hybrid PLA (fiber)

L

L

ODU ODU ODU ASNK 52 ASNK-52 ASNK-52 ASNK-52 PSU2 (slot11)

PoE

Remote site

LAN3

PSU1 (slot9)

10G SFP+

1G SFP

RIM (slot7)

DRI (slot8)

CTL2 (slot5)

LIM (slot6)

RIM/DRI (slot3)

RIM/DRI (slot4)

AGS20L FAN (slot10/12)

Local site

CTL1 (slot1)

1Link in Multiband IDU AGS20L is the aggregator between : •ODU ASN / ASNK 1+0 / 2+0 FD / 2+0 XPIC (RIM card slot7) •80HDX Carrier 1+0 (DRI card slot8)

PoE

LIM (slot2)

AGS20L FW 1.1.0 80HDX FW 1.6 - HPLA

MBL AGS20L & 80HDX ODU

ODU 80HDX PHY1 Carrier PHY2

PHY1 80HDX PHY2 Carrier LAN3 LAN4

H

up to 10Gbps

XPIC Hybrid PLA (fiber)

10G SFP+

(slot11)

PSU1 (slot9)

FAN (slot10/12)

AGS20L PSU2 1° istance



Only Local Mngt (fiber)

1G SFP

RIM (slot7)

DRI (slot8)

CTL2 (slot5)

LIM (slot6)

RIM /DRI istance (slot3) CTL1 (slot1)

RIM /DRI (slot4) LIM (slot2)

L

Orthomode Coupler

Orthomode Coupler

H

L

ODU ASNK 52 ASNK-52

H

Remote site

LAN3 LAN4 XPIC Hybrid PLA (fiber)

Only Local Mngt (fiber)

L

ODU ODU ODU ASNK 52 ASNK-52 ASNK-52 ASNK-52 AGS20L 1° istance PSU2 (slot11)

PSU1 (slot9)

FAN (slot10/12)

Local site



10G SFP+

1G SFP

RIM (slot7)

DRI (slot8)

CTL2 (slot5)

LIM (slot6)

RIM/DRI (slot3) istance CTL1 (slot1)

RIM/DRI (slot4) LIM (slot2)

1Link in Multiband IDU AGS20L is the aggregator between : •ODU ASN / ASNK 1+0 / 2+0 FD / 2+0 XPIC (RIM card slot7) AGS20L FW 1.1.2 (up to 2 istance of HPLA) •80HDX Carrier 1+0 (DRI card slot8) 80HDX FW 1.4.32 - HPLA on PHY1 ONLY

MBL AGS20M & 80HDX Local site

ODU

ODU 80HDX PHY1 Carrier PHY2

PHY1 80HDX PHY2 Carrier LAN3 LAN4

H

up to 10Gbps

XPIC Hybrid PLA (fiber)

Only Local Mngt

L

Orthomode Coupler

Orthomode Coupler

H

L

ODU ASNK-52 ASNK 52

H

L

ODU ODU ASNK-52 ASNK-52

Remote site

LAN3 LAN4 XPIC

ODU ASNK 52 ASNK-52

Hybrid PLA (fiber)

Only Local Mngt

PoE ODU A

ODU B

PoE

ODU A ODU B

XGLANA LAN1 10Gbps SFP+ 1G RJ45

XGLANA LAN1 10Gbps SFP+ 1G RJ45

ODUA, ODUB and XGLANA, ETH RLAG L1 on port Ex 0/x

10G Mode = Mixed Management cable can be used : 80HDX - LAN3 copper or LAN2 fiber AGS20M N34030 1.1.0 & 80HDX N60052 1.4.32

MBL AGS20 & 80HDX Local site Hybrid PLA

ODU

ODU 80HDX PHY1 Carrier PHY2

PHY1 80HDX PHY2 Carrier LAN3 LAN4

H

up to 10Gbps

XPIC Only Local Mngt

L

Orthomode Coupler

Orthomode Coupler

H

L

ODU ASNK-52 ASNK 52

H

L

ODU ODU ASNK-52 ASNK-52

Remote site

LAN3 LAN4 XPIC

Only Local Mngt

Hybrid PLA

ODU ASNK 52 ASNK-52

PoE ODU A

ODU B

LANC 2.5Gbps SFP

PoE

LAN4 1G RJ45

ODU A ODU B

LANC 2.5Gbps SFP

LAN4 1G SFP

ODUA, ODUB and LANC, ETH RLAG L1 on port ODUA

10G Mode = Mixed Management cable can be used only 80HDX - LAN3 AGS20 N31030 1.13.1 & 80HDX N60052 1.4.0

Single Antenna Multiband OMT coupler

OMT Coupler

80HDX position

Two ODU ASNK-52 (Only For 15/18/23GHz)

One Antenna

ALFO+80HDX 2x(1+0) XPIC (no RLAG) PHY 1 PHY 2 LAN3 LAN4 XPIC

Vertical

XPIC LAN4 LAN3 PHY 2

Horizontal

H

H

80HDX XPIC H

Third party equipment

Antenna Orthomode

Coupler Orthomode

L

20Gbps

PHY 1 2x10Gbps

80HDX XPIC V

80HDX XPIC V

Local Radio

20Gbps 2000MHz@128QAM 10Gbps 1000MHz@256QAM 8.5Gbps 750MHz@256QAM 5.5Gbps 500MHz@256QAM 2.6Gbps 250MHz@256QAM

L

Remote Radio

PHY 1 PHY 2 LAN3 LAN4 XPIC

Vertical

XPIC LAN4 LAN3 PHY 2

Horizontal

PHY 1

80HDX XPIC H 2x10Gbps

LLF enabled

Third party equipment

1 Link in 2+0 XPIC without Ethernet Radio LAG V 1 frequency channel = Data/Inband 10Gbps 2 polarizations = LAN3 dedicated for FMP = Xpic cable F03735 10 Giga mode : Enable H Aggregation/Carrier : Disable Radio Configuration : CCDP = Co Channel Dual Polarized 80HDX XPIC V f1(v) tx active - rx active CCDP SynchE is mandatory 80HDX XPIC H f1(h) tx active - rx active NEW FW 1.6.0

ODU characteristics ALFOplus80HDX (Part number Siae from GB9920-01 to GB9921-01) ALFOplus80HDX description Frequency range

71 to 86 GHz

Modulation

4FQAM, 4HQAM, 4SQAM, 4QAM, 4QAM LP,16SQAM, 16QAM, 32QAM, 32QAM LP, 64QAM, 64QAM LP, 128QAM, 128QAM LP, 256QAM

Bandwidth [Nr of Channels]

62.5(4FQAM), 125(4HQAM), 250 [19], 500 [9], 750 [5], 1000 [4], 2000MHz [2]

Radio Net Throughput

10Gbit/s

Protection scheme

1+0; 2+0 ACAP; 2+0 XPIC ; Multiband Radio Link (HPLA)

Tx Dynamic Attenuator

20 dBm

Maximum transmit power

+20dBm@4F/4H/4S/4QAM; +17dBm@16/32QAM; +15dBm@64QAM; +14dBm@128QAM;+13dBm@256QAM

Receiver Sensitivity BER10^-6

-78dBm@ 62.5MHz ; -78@125MHz ; -77.5dBm@250MHz ; -74.5dBm@500MHz ; -72.5dBm@750MHz ; -71dBm@1000MHz ; -68dBm@2000MHz ;

4FQAM =Fourth of Baud rate [Throughput ≈ Bandwidth/4 * Log2(Modulation) * 42,48%(due of Strong-FEC)] 4HQAM = Half of Baud rate [Throughput≈Bandwidth/2 * Log2(Modulation) * 42,48%(due of Strong-FEC)] 4SQAM = Strong [Throughput≈Bandwidth * Log2(Modulation) * 42,48%(due of Strong-FEC)] 4QAM = [Throughput≈Bandwidth * Log2(Modulation) * 72,09%(due of FEC)] 16SQAM= Strong [Throughput≈Bandwidth * Log2(Modulation) * 42,48%(due of Strong -FEC)] 16QAM = [Throughput≈Bandwidth * Log2(Modulation) * 72,09%(due of FEC)] The "LP" suffix ("Low Power") means that modem transmits with a TX power equal to the upper modulation that the reference one.

NEW FW 1.2.0

Radio Net Throughput 1+0 Radio Net throughput [Mbps] without XPIC Bandwidth

4-F QAM

4-H QAM

4-S QAM

4 QAM

16-S QAM

16 QAM

32 QAM

64 QAM

128 QAM

256 QAM

62.5MHz

-

-

51.2

87.3

103.1

175.4

219.5

263.5

307.6

351.6

125MHz

-

53.4

106.9

182.5

215.3

366.5

458.6

550.6

642.6

734.6

250MHz

54.3

108.6

217.3

369.8

436.1

741.1

926.7

1112.4

1298.0

1483.7

500MHz

109.1

218.3

436.5

741.8

874.6

1485.2

1856.8

2228.5

2600.2

2971.9

750MHz

166.4

332.9

665.8

1130.8

1333.1

2263.2

2829.3

3395.5

3964.7

4527.9

1000MHz

215.9

431.8

863.7

1466.6

1728.8

2934.6

3668.5

4402.5

5136.5

5870.5

2000MHz

424.8

849.6

1699.2

2883.9

3398.4

5474.4

6843.4

8212.4

10021.4

-

1+0 Radio Net throughput [Mbps] with XPIC Bandwidth

4-F QAM

4-H QAM

4-S QAM

4 QAM

16-S QAM

16 QAM

32 QAM

64 QAM

128 QAM

256 QAM

62.5MHz

-

-

-

-

-

-

-

-

-

-

125MHz

-

-

-

-

-

-

-

-

-

-

250MHz

48.8

97.6

195.3

332.4

392.0

666.2

833.1

1000.0

1166.9

1333.8

500MHz

102.7

205.4

410.7

698.0

823.0

1397.5

1747.3

2097.1

2556.8

2796.6

750MHz

157.7

315.4

630.8

1071.6

1263.3

2144.7

2681.2

3217.8

3754.3

4290.9

1000MHz

209.2

418.4

836.9

1421.0

1675.2

2843.6

3554.8

4266.1

4977.3

5688.6

2000MHz

420.7

841.4

1682.8

2856.7

3367.3

5424.4

6780.9

8137.4

9930.0

NEW FW 1.6.0

ANTENNA polarisation Use lubricant grease Dow Corning 4 around O-Ring in order to avoid that the rubber is dried and water, sand, dust could enter into the waveguide.

V60707 Twist -adapter

WRONG MOUNTING

ODU side

Antenna side

reference VERTICAL POLARIZATION

reference HORIZONTAL POLARIZATION

ODU Flange

TwistAdpt

Antenna Feed

ODU mounting 4 6 3

7 5

1+0 branching loss : 0dB

1 2

Tighten the 4 screws in order crossed, first on one diagonal and after on the other. Use oil ant-seizing between the threads of nuts and bolts because often lack of lubrication could cause metal parts seized together.

1- In the top of Antenna, remove the tape and plug the cap. 2- In the bottom of Antenna, remove the cap to drain out the water or Humidity.

8 Leave 25 cm straight Lan cable between Rosenberger connector and first bending to secure waterproof IPX5.

2+0 mounting 2+0 OMT loss ≤ 1dB

Antenna Alignment

XPD ±5° ± ° Azimut Elevation

XPDmeter

XPDmeter80.exe is a MS-DOS application, that allows local and remote XPD statistics acquisition, as well used for correct antenna rotation. 2 – XPD rotation assistance Command interface MS Dos like

Aggregator

Coupler rotation ±5°

Multi-meter 0V

Carrier

MNGT LAN3

1 – execute xpdm80.exe Loc_Aggreg Loc_Carrier Rem_Aggreg

3V

3 – check Voltage measured on Carrier RSSI

3Volt = excessive XPD (more than 35dB) 1.5Volt = optimal XPD (between 29÷35dB) 0Volt = Insufficient XPD (less then 29dB)

MNGT LAN3

1.5V

Rem_Carrier

UPD port 56020, 56021

Coupler rotation ±5°

XPIC – cross Polarization Interference Canceller Horizontal (H) XPIC OMT Antenna TX

OMT H&V

Polarization alignment ± 5°

OMT H&V

H RX V

Vertical (V)

Connection to Radio equipment • On MNGT port with F03667 dedicated cable (!!Need to know the ip address of radio!!). The PC must be set in the same subnet. • On 48V port with F03622 dedicated cable using HyperTerminal (115200bps 8-N-1-N) (!!Doesn’t need to know the ip address of radio!!) • Using Rescue login (!!when you have forgotten the ip address!!) during the reboot you can manage the NE using 172.20.253.13/16 for all the LAN interfaces. Software

N.E. ( Network Element )

Backup/Restore

Protocol

Internet Browser (I.E. 9) you cannot load firmware and backup/restore

WEBLCT Loc&Rem

NO

HTTP

Web Lct Console ≥ 1.2.2 (WinXp, Win7) Free software downlodable www.siaemic.com after registration

WEBLCT Loc&Rem

YES (File.bak)

HTTP, FTP

NMS5-LX (Linux) ≥ 8.2.1

1000

YES (File.bak)

FTP , SNMP

NMS5-UX (Unix) ≥ 8.2.1

10000

YES (File.bak)

FTP , SNMP

PHY1, PHY2, LAN3 and LAN4 are disabled in factory setting

NEW FW 1.6.0

1 - Connecting Via Lan Don’t use

Rescue connection allows only the operations: • recovering IP Address • recovering by Factory default procedure • recovering by Firmware Update • Restore a backupfile.bak

3 – press double click 2 – Enter the IP address of equipment

WEBLCT Max 4 Users connected in the same time.

1 - Connection on MNGT port 2 – type the Radio IP address 3 – Default Username (R/W): admin Default Password: admin Console

admin admin

LAN/MNGT

RS232 Telnet SM-OS

HTTP WebLCT

MIB Default factory IP address: ODU HIGH 172.20.255.15/16 ODU LOW 172.20.254.14/16

Network Element

WEBLCT Open WEB LCT of Remote Link Radio

Radio Status

hide / show menu

Alarms

manual refresh

Radio Setting

This Web Browser manages a single terminal.

TELNET Connection 1 - Connection on 48V port (RS232 console) at 115200bps 8-N-1-N or connection on MNGT port via Telnet session IPAddress:23

SIAE Microelettronica Operating System SM-OS login: admin Password: admin SM-OS# show ip interface vlan1 is up, line protocol is up Internet Address is 192.168.79.90/24 Broadcast Address 192.168.79.255 Vlan counters disabled SM-OS#

MNGT Port

Max 7 CLI sessions in the same time.

Used for Ethernet Switch and Mngt config only

CLI: Access and exit command mode Command

Purpose

SM-OS login: admin Password: admin

# Login in Privileged EXEC

SM-OS# logout

# Logout

SM-OS# configure t SM-OS(config)#

# Enter Global Configuration mode ( with the char "!" you can move anytime in SM-OS(config-if)# )

SM-OS(config)# interface SM-OS(config-if)#

# Enter Interface Configuration mode value : ex 0/1 = XGLAN (10Gbps) or LAN1 (1Gbps/2.5Gbps) ex 0/2 = TRX gi 0/1 = LAN4 gi 0/3 = LAN2 gi 0/6 = LAN3 gi 0/7 = MNGT

SM-OS(config-if)# exit SM-OS(config)#

#To return to global configuration mode

SM-OS(config-if)# end SM-OS#

#To return to privileged EXEC mode

SM-OS# show running-config

#Show the actual running configurations on Ethernet Switch

Example 1 (Disable XGLAN interface) SM-OS# configure t SM-OS(config)# interface ex 0/1 SM-OS(config-if)# shutdown SM-OS(config-if)# end SM-OS#

CLI: getting Help Command

Purpose

help

Provides a brief description of the help system in any command mode (Q to quit )

Abbreviated-command-entry?

Provides a list of commands that begin with a particular character string. (No space between command and question mark.)

Abbreviated-command-entry

Completes a partial command name.

?

Lists all commands available for a particular command mode.

Command ?

Lists the keywords or arguments that you must enter next on the command line. (Space between command and question mark).

Command1;Comand2;Command3

Sequence of commands to perform

Example 2 (complete command) type config and press button SM-OS# config EXEC commands : config-restore {flash | remote ip-addr file | norestore} configure Example 3 (list of keywords) configure terminal Type config and press ? SM-OS# config? SM-OS# config config-restore configure Commands starting with config SM-OS# config Example 4 (multiple commands) SM-OS# c t;interface ex 0/1 ;shutdown;mtu 1500;no shutdown SM-OS(config-if)#

1+0 Line up Procedure 1.

10 Giga Mode [Baseband > Ethernet > 10 Giga Mode: Enable or Disable or Mixed ] •

2.

3.

4.

Radio Configuration : •

Radio Configuration: 1+0 [Equipment >Radio Configurator]



Bandwidth & Modulation/Link ID [Equipment >BW & Mod. / Link ID]



Tx Frequency [Radio Branch > ODU Settings]



Tx Power control [Radio Branch > ODU Powers].

DCN Management Configuration: •

MNGT Port configuration [Base Band > DCN > MNGT Port Configuration]



Agent IP address [Main> Equipment Properties]



Remote element List

Synchronisation Config: •

5.

Port Protection [Baseband > Ethernet > Port Protection]

Quality, T0 priority and SSM [Synchronisation > SETS]

ETHERNET Configuration

NEW FW 1.3.0

1. 2. 3.

10 Giga Mode [Baseband > Ethernet > 10 Giga Mode : Enable] Bridge Mode Config [Baseband > Ethernet > Bridge Mode Conf.] Port Manager [Base Band > Ethernet > Port Manager] •

4.

VLAN •

5.

Port Alarm Report: Disabled

Bandwidth & Modulation/Link ID [Equipment >BW & Mod. / Link ID] Tx Frequency [Radio Branch > ODU Settings] Tx Power control [Radio Branch > ODU Powers]. Radio Configuration: XPIC H or XPIC V [Equipment >Radio Configurator] Fault Management Procedure = Disabled during Lineup [Equipment > XPIC]

Aggregation / Carrier [Equipment >Aggregation & Carrier] • • • •

9. 10.

Include LAN3 in Member ports of Management VLAN (VLAN1)

Remote element List Radio Configuration: • • • • •

8.

[Base Band > Ethernet >VLAN]

MNGT Port configuration [Baseband > DCN > MNGT Port Configuration] •

6. 7.

LAN3 LOS: Disabled; XGLAN, TRX and LAN3 Admin state: Enabled

2+0 XPIC Line up

Aggregator Preferential or Carrier Preferential [Equipment >Aggregation & Carrier] Line Protection & switch criteria [Equipment >Aggregation & Carrier > Line Protection] Manual Operation Timeout = 0 Force the role Aggregator in the units Aggregator-(Prefer.) and Force the role Carrier in the units Carrier-(Prefer.)

Connect the LAN cables (Physical 1, Physical 2, LAN3 and Management LAN) Synch Ethernet config [Synchronisation > SETS] NEW FW 1.2.0

MBL 80HDX & ALFO+2 Line up 1.

10 Giga Mode

2.

Radio Configuration :

[Baseband > Ethernet > 10 Giga Mode: Mixed]



Radio Configuration: 1+0 [Equipment >Radio Configurator]



HPLA Aggregator over Physical Interface 2 [Equipment >Aggregation & Carrier]



Bandwidth & Modulation/Link ID [Equipment >BW & Mod. / Link ID]



Tx Frequency [Radio Branch > ODU Settings]



Tx Power control [Radio Branch > ODU Powers].

3. 4.

Bridge Mode Config [Baseband > Ethernet > Bridge Mode Conf.] Port Manager [Base Band > Ethernet > Port Manager]

5.

VLAN

6. 7. 8.

MNGT Port configuration [Baseband > DCN > MNGT Port Configuration] Remote element List Synch Ethernet config [Synchronisation > SETS]

[Base Band > Ethernet >VLAN]

MBL 80HDX & ALFO+2 Line up Requisite minimum : •HPLA doesn’t work with Bandwidth 62.5MHz and 125MHz •Set 2.5Gbps LAN2 of 80HDX and LAN2 of ALFO+2 (other speed setting are not supported) •Synchronization (SETS, SSM) must be congruent between 80HDX and ALFO+2 •Configure on Local 80HDX that SSM messages are sent on the aggregated channel (LAN2 and TRX) •If Radio Encryption is used, this function must be enabled both 80HDX and ALFO+2 •MAB isn’t supported for hybrid aggregation

Procedure 80HDX: 1. Set 10Giga mode = Mixed and 1+0 radio Config 2. Set Physical Interface 2 = HPLA Aggregator 3. Enable LAN3, 10Gbps XGLAN, 2.5Gbps LAN2 4. Managemnt VLAN must include MNGT, TRX, LAN3

Procedure ALFO+2: 1. Enable LAN3 and LAN2 with LAN2 in 2.5Gbps 2. Managemnt VLAN must include MNGT, LAN3 3. Enable HPLA on LAN2 First in Remote and then in Local 80HDX could be in CB or PEB depending VLAN config.

5 80HDX FW N60052 1.3.0 ALFO+2 FW N50052 1.6.1

3

1

4 2

ALFOplus2

80HDX FW 1.3.0 & AP2 FW 1.6.1

MBL 80HDX & ALFO+2 Line up

Hitless Zone

The link is working under the Hitless profile

Bad Zone

The aggregator is not able to guaranteed the lower profile +1 and ha remove 80GHz link from HPLA (ALFOplus2 link works only).

Disqualified

The Aggregator has removed the Carrier from the HPLA (80GHz link works only).

It’s always present SINCE 80HDX FW 1.4.32 and ALFOplus2 FW 1.6.1

MBL AGS20L & 80HDX Line up 1.

10 Giga Mode

2.

Radio Configuration :

[Baseband > Ethernet > 10 Giga Mode: Mixed]



Radio Configuration: 1+0 [Equipment >Radio Configurator]



HPLA Carrier over Physical Interface 1 [Equipment >Aggregation & Carrier]



Bandwidth & Modulation/Link ID [Equipment >BW & Mod. / Link ID]



Tx Frequency [Radio Branch > ODU Settings]



Tx Power control [Radio Branch > ODU Powers].

3. 4.

Bridge Mode Config [Baseband > Ethernet > Bridge Mode Conf.] The "Carrier" is been validated Port Manager [Base Band > Ethernet > Port Manager] in Customer Bridge only

5.

VLAN

6. 7. 8.

MNGT Port configuration [Baseband > DCN > MNGT Port Configuration] Remote element List Synch Ethernet config [Synchronisation > SETS]

[Base Band > Ethernet >VLAN]

AGS20L FW 1.1.2 80HDX FW 1.4.0

MBL AGS20M & 80HDX Line up 1.

10 Giga Mode

2.

Radio Configuration :

[Baseband > Ethernet > 10 Giga Mode: Mixed]



Radio Configuration: 1+0 [Equipment >Radio Configurator]



HPLA Carrier over Physical Interface 1 [Equipment >Aggregation & Carrier]



Bandwidth & Modulation/Link ID [Equipment >BW & Mod. / Link ID]



Tx Frequency [Radio Branch > ODU Settings]



Tx Power control [Radio Branch > ODU Powers].

3. 4.

Bridge Mode Config [Baseband > Ethernet > Bridge Mode Conf.] The "Carrier" is been validated Port Manager [Base Band > Ethernet > Port Manager] in Customer Bridge only

5.

VLAN

6. 7. 8.

MNGT Port configuration [Baseband > DCN > MNGT Port Configuration] Remote element List Synch Ethernet config [Synchronisation > SETS]

[Base Band > Ethernet >VLAN]

AGS20M FW 1.1.0 80HDX FW 1.6.0

MBL AGS20 & 80HDX Line up 1.

10 Giga Mode

2.

Radio Configuration :

[Baseband > Ethernet > 10 Giga Mode: Mixed]



Radio Configuration: 1+0 [Equipment >Radio Configurator]



HPLA Carrier over Physical Interface 2 [Equipment >Aggregation & Carrier]



Bandwidth & Modulation/Link ID [Equipment >BW & Mod. / Link ID]



Tx Frequency [Radio Branch > ODU Settings]



Tx Power control [Radio Branch > ODU Powers].

3. 4.

Bridge Mode Config [Baseband > Ethernet > Bridge Mode Conf.] The "Carrier" is been validated Port Manager [Base Band > Ethernet > Port Manager] in Customer Bridge only

5.

VLAN

6. 7. 8.

MNGT Port configuration [Baseband > DCN > MNGT Port Configuration] Remote element List Synch Ethernet config [Synchronisation > SETS]

[Base Band > Ethernet >VLAN]

AGS20 FW 1.13.0 80HDX FW 1.4.0

10 Giga mode and Port Protection “10 Giga Mode Enable” means that Physical 1 and Physical 2 working at 10Gbps. It is used in radio config : 1+0 or 2+0 ACAP or 2+0 XPIC or EPP Disable means Phy1=LAN1 and Phy2=LAN2 can be used indipendently 1/2.5Gbps. Mixed is used when Phy1=10G and Phy2=1/2.5G and H-PLA radio config (MBL) Two independent 10Gbps interfaces XGLAN1 (ex 0/1) and XGLAN2 (gi 0/3)

This operation is traffic affective with an automatic HW restart Port Protection (EPP) is used when you want use PHY2 (10Gbps) as protection of PHY1 (10Gbps)

This menu is available only when “10 Giga mode: Enable” and “physical interface 2 : Disabled“ [in the menu Equipment > Aggregation&Carrier > Aggregation/Carrier] NEW FW 1.6.0

Radio Configurator

1

1+0 or 2+0 Frequency Diversity Enable XPIC. According with ODU HW installation polarization set the proper SW configuration

Manage L1 RLAG between PHY and Radio directions

1

PHY2 is used as aggregator port (in 2+0 FD or XPIC) No Aggregation or Carrier config

PHY2 is used as Carrier port (in 2+0 FD or XPIC) PHY1 is used as Hybrid port MBL AGS20L/M PHY2 is used as Hybrid port MBL AGS20/L

Physical interface 1

PHY2 is used as Hybrid port MBL ALFO+2

2

Physical interface 2

This menu is available only when “10 Giga mode” is : •Enable [the options are Disable, Aggregator (Preferential), Carrier (Preferential), HPLA Carrier] or •Mixed [the options are Disable, HPLA Carrier, HPLA Aggregator ]

LAN2 Gi 0/3 1Gbps/2.5Gbps

Switch Ex 0/1 Ethernet Ex 0/2

XGLAN 10Gbps LAN1 1/2.5Gbps TRX 10Gbps

Layer 1 RLAG

To Radio

NEW FW 1.6.0

Aggregation & Carrier This menu is available only when the ODU works as Aggregator or Carrier

In this menu is possible Enable (UP) or Disable (Down) the PHY1 and PHY2

SFP Status 3

Actual values NEW FW 1.3.0

Protection Configuration 1 2

This menu is available only when “10 Giga mode is Enable” and “Physical interface 2 is setted as Aggregator (Preferential) or Carrier (Preferential)

3 Line Protection Config. allows to protect traffic (Data & Mngt) incoming from Aggregator-preferential ports by “switch-over” to the Carrier-preferential ports. According with management plane is possible define the Port Switch Criteria

4 Manual Operation

This menu is available only when “Line Protection Configuration is Enabled”

5 NEW FW 1.3.0

Bandwidth & Modulation / Link ID Theoretical Capacity ≈ Bandwidth x Log2(Modulation) During antenna aiming ACM & ATPC must be disabled

change one configuration per time.

Exclude ODU in PLA/HPLA when the modulation is = lower profile +1

NEW FW 1.2.0

Tx Power Ramp mode TX power

dBm +20

1000MHz@4QAM Ptx=max

ACM =Enabled Lower Profile = 4-F QAM Upper Profile = 256 QAM

+19

Ramp to Ref Modulation (Tx power max allowed for each modulations)

+18 +17 +16

1000MHz@4QAM Ptx=+16dBm

Ramp to Tx Power limit (Max Tx power fixed by Operator)

+15 +14 +13

1000MHz@256QAM Ptx=max

4F 4H 4S

Tx power constant for each modulation

4 4LP 16S 16 32 32LP 64 64LP 128 128LP 256

QAM

Ramp to Tx Power limit

Tx Power Ramp to Ref. Modulation Reference Modulation

TX power

dBm +20

NO

+19 +18 +17 +16

1000Hz@32QAM Ptx=MAX

+15 +14 +13 Modulation

4F 4H 4S

4 4LP 16S 16 32 32LP 64 64LP 128 128LP 256

QAM

Local Link ID • LLI has the function to identify and filter the radio frame (send label and expected label must be equal) • Local Link radio IDentifier is used to avoid unwanted radio frame

Example (2 Radio Link different traffic in the same direction and close to each other)

Radio A1

Radio A2 LLI=10

PRX A2 A1

D Radio B1

LLI=20 In case of Failure

PRX B2 Radio B2

A1

If LLI.B2≠LLI.A1, no traffic in output

Radio Branch: Frequencies Set Channel frequency or Tx Frequency in Remote and Local ODU and after Press apply & confirm

3 1

2  Traffic ok (normal setting)  Temporary Tx off with Timeout  Permanent Tx off without Timeout

 no modulator (no traffic)  traffic ok

5 Local High FTx1A=83500.0MHz FRx1A=73500.0MHz

Value of Timeout Remote 71000 MHz 74750 MHz Low FTx1A=73500.0MHz FRx1A=83500.0MHz

ODU 1L

78500 MHz

82250 MHz

ODU 1H

86000 MHz

1 SubBand

Radio Branch: Powers

Manual: TX Power Fixed; Automatic: ATPC enabled ATPC allows Ptx> Ethernet

Tab

Bridge Mode Conf. Port Manager

VLAN

Physical Interface

Basic Settings

Port Settings

Static VLANs

Management Ctag allowed on CNP/CEP ports in PEB using N60052 v01.00.00

Parameter

Value

Bridge Mode

Provider Edge Bridge

Port

Description

Admin State

Auto Neg.

Duplex

Speed

MTU

Bridge Port Type

Ex0/2

TRX

Enabled

No

Full

10Gb

12000

Provider Network Port

Ex0/1

XGLAN

Enabled

Yes

Full

10Gb

12000

Customer Network

Gi0/3

LAN2

Disable

Yes

Full

1 Gb

12000

Provider Network Port

Gi0/6

LAN3

Enabled

Yes

Full

1 Gb

12000

Customer Network

Gi0/1

LAN4

Disable

Yes

Full

1 Gb

12000

Provider Network Port

Global MAC Learning Status

Enabled

MAC Add. Table Aging Time

300

Unicast MAC Learning Limit

16000

Port

Acceptable Frame Types

Ingress Filtering

PVID

Default User Priority

Gi0/7 MNGT

All

Enabled

127

7

Gi0/6 LAN3

Untagged and Priority Tagged

Enabled

103

0

ex 0/2 TRX

All

Enabled

1

0

ex 0/1 XGLAN

Untagged and Priority Tagged

Enabled

101

0

VLAN ID

VLAN Name

Member Ports

Untagged Ports

Ether Type

1

Not_Used

Gi0/7

Gi0/7

0x88a8

101

pipe1

Ex0/1, Ex0/2

Ex0/1

0x88a8

103

pipe3

Gi0/6, Ex0/2

Gi0/6

0x88a8

127

InBand

Ex0/1, Ex0/2, Gi0/7

Gi0/7

0x88a8

NEW FW 1.1.0

SCENARIO InBand #ALFOplus80HDX configuration inband(vlan 127) on XGLAN (Please Download this script using console port) #MTU < = 12000 byte and Provider Edge Bridge (PEB) c t ; system mtu 12000 ; bridge-mode provider-edge ; end #sleep 20 second Sleep 20; c t #set CNP and Enable XGLAN interface ex 0/1 ; bridge port-type customerNetworkPort port-based ; switchport svlan-priotype copy ; no shutdown ; exit #Create Pipe Local_XGLAN to Remote_XGLAN vlan 101; ports ex 0/1 ex 0/2 untagged ex 0/1 name pipe1 ; exit #XGLAN configuration interface ex 0/1 ; switchport pvid 101 ; switchport ingress-filter ; switchport priority default 0; switchport dot1q ingress ether-type 0x1; exit #set CNP and Enable LAN3 interface gi 0/6 ; bridge port-type customerNetworkPort port-based ; switchport svlan-priotype copy ; no shutdown ; exit #Create Pipe Local_LAN3 to Remote_LAN3 vlan 102 ; ports ex 0/2 gi 0/6 untagged gi 0/6 name pipe3 ; exit #LAN3 configuration interface gi 0/6 ; switchport pvid 103 ; switchport ingress-filter ; switchport priority default 0; switchport dot1q ingress ether-type 0x1; exit #TRX configuration interface ex 0/2 ; bridge port-type ProviderNetworkPort ; switchport pvid 1 ; switchport ingress-filter ; switchport priority default 0 Shutdown ; no negotiation ; speed 10000 ; no shutdown ; exit #Management Port configuration interface gi 0/7 ; switchport ingress-filter ; switchport priority default 7 ; no shutdown ; exit #configure INBAND VLAN on XGLAN=ex 0/1, TRX=ex 0/2, MNGT=gi 0/7 vlan 127 ; ports ex 0/1 ex 0/2 gi 0/7 untagged gi 0/7 name InBand ; exit ; default ip vlan id 127 #Set new Ip address SubnetMask and default gateway default ip address 192.168.79.90 subnet-mask 255.255.255.0 ; default gateway route 192.168.79.1 ; end set hitless-restart enable ; sleep 5 ; reload

DHCP on LAN4 Port PHY1 (ex 0/1)

Switch

PHY2 (gi 0/3) VLAN 2

192.168.79.0/24 TRX (ex 0/2)

TRX (ex 0/2)

Switch

PHY2 (gi 0/3) VLAN 2

LAN3 (gi 0/6)

LAN3 (gi 0/6)

LAN4 (gi 0/1) VLAN 3

VLAN 3

MNGT (gi 0/7) Interface vlan 3 (192.168.0.1/30)

PHY1 (ex 0/1)

LAN4 (gi 0/1) MNGT (gi 0/7)

Router

Interface vlan 2 (192.168.79.90/24)

Interface vlan 2 (192.168.79.91/24)

Router

Interface vlan 3 (192.168.0.5/30)

Local script

Remote script

ct Vlan 2; ports ex 0/2 gi 0/7 untagged gi 0/7 name DCN; exit default ip vlan id 2 default ip address 192.168.79.90 subnet-mask 255.255.255.0 default gateway route 192.168.79.1

ct Vlan 2; ports ex 0/2 gi 0/7 untagged gi 0/7 name DCN; exit default ip vlan id 2 default ip address 192.168.79.91 subnet-mask 255.255.255.0 default gateway route 192.168.79.1

#CREATE on LAN4 vlan 3; ports gi 0/1 untagged gi 0/1 name ELAO; exit interface gi 0/1 ; switchport pvid 3 ; no shutdown ; exit interface vlan 3 ip address 192.168.0.1 255.255.255.252 ; no shutdown exit service dhcp-server ; ip dhcp ping packets ip dhcp pool 1 network 192.168.0.1 255.255.255.252 192.168.0.2 lease 0 0 5 ; default-router 192.168.0.1 ; exit ip route 192.168.0.4 255.255.255.252 192.168.79.91

#CREATE on LAN4 vlan 3 ; ports gi 0/1 untagged gi 0/1 name ELAO; exit interface gi 0/1 ; switchport pvid 3 ; no shutdown ; exit interface vlan 3 ip address 192.168.0.5 255.255.255.252 ; no shutdown exit service dhcp-server ; ip dhcp ping packets ip dhcp pool 1 network 192.168.0.5 255.255.255.252 192.168.0.6 lease 0 0 5 ; default-router 192.168.0.5 ; exit ip route 192.168.0.0 255.255.255.252 192.168.79.90 NEW v01.02.00

IN BAND L3 10.0.1.0/29 PHY1 (ex 0/1)

10.0.1.8/29

Switch

PHY2 (gi 0/3) vlan 5

Switch TRX (ex 0/2)

TRX (ex 0/2)

PHY2 (gi 0/3) vlan 5

LAN3 (gi 0/6)

LAN3 (gi 0/6)

LAN4 (gi 0/1) vlan 4

vlan 4

MNGT (gi 0/7) Interface vlan 4 (10.0.1.2/29)

PHY1 (ex 0/1)

LAN4 (gi 0/1) MNGT (gi 0/7)

Router

Interface vlan 5 (10.0.1.2/29)

Interface vlan 5 (10.0.1.9/29)

Router

Interface vlan 4 (10.0.1.9/29)

Local script

Remote script

configure terminal #CREATE Vlan 4 ; ports gi 0/1 gi 0/7 untagged gi 0/1 gi 0/7 name DCN_MNGT exit default ip vlan id 4 default ip address 10.0.1.2 subnet-mask 255.255.255.248 default gateway route 10.0.1.1

configure terminal #CREATE Vlan 4 ; ports gi 0/1 gi 0/7 untagged gi 0/1 gi 0/7 name DCN_MNGT exit default ip vlan id 4 default ip address 10.0.1.9 subnet-mask 255.255.255.248

#CREATE vlan 5; ports ex 0/2 name DCN_RADIO; exit interface vlan 5 ip unnumbered vlan 4 no shutdown ; exit ip route 10.0.1.8 255.255.255.248 vlan 5 ; exit set hitless-restart enable Reload

#CREATE vlan 5; ports ex 0/2 name DCN_RADIO; exit interface vlan 5 ip unnumbered vlan 4 no shutdown ; exit ip route 10.0.1.0 255.255.255.248 vlan 5 ; exit set hitless-restart enable Reload

NEW v01.02.00

OSPF Open Shortest Path First

•It is a dynamic routing protocol that calculate the shortest route to a destination through the network based on Dijkstra algorithm. •In case of link failure, OSPF search for alternative paths in order to keep all the networks connected •Each link has assigned a weight cost (high capacity links are preferred to the low capacity ones) Metric_Cost= 10^8/Bandwidth Interface[bps]

NEW v01.02.00

Web LCT: Main Menu – Equipment Properties

Agent IP Equipment ID: name view of radio

In case of static routing the Agent IP = IP Ethernet (MNGT port)

Restart without cut the traffic Network Element Agent IP address

CPU Interface VLAN 1 LAN (Mngt)

SWITCH (VLAN)

TRX (IB/OOB L2)

Agent IP is used to identify the Network Element and Set/Get SNMP commands or Traps alarms.

Routing Table ALFOplus80HDX uses Routing Table to route the management traffic through its interface VLAN. “Routing table” is used for view the actual routing mapped

Connected: static routing inserted automatically by controller. (Cannot be delete) Static: static routing inserted manually by the user (Can be delete)

- Destination: is the Network address to send /receive management traffic. - Subnet Mask: Network Mask of the destination network. - Gateway: is the next IP address interface that connect the Destination's net. - Interface: defines the local mngt interface that allows to reach the next hop - Protocol: specifies how the routing row has been inserted. Example 6 (set default gateway) SM-OS# c t; SM-OS(config)# ip route 0.0.0.0 0.0.0.0 192.168.79.1

... or using CLI show ip interfaces show ip route show ip arp

Remote element List In order to know and manager the remote Network Element, local equipment is declared “managed by SCT”, remote one is declared “remote link”. Opposite configuration on remote side. Create Station and Insert the Network Element using the IP AGENT

Open/close menu

1

9

5

4 192.168.79.90 ALFO+80HDX

2

192.168.79.91

3 ALFO+80HDX

6

7 8

General Preset Rx Power Low (by default -70dBm): pre-alarm threshold configurable by operator (independence of errors)

Prx This label will be shown in the Event list

If Prx ≤ Rx Signal Alarm Threshold, then the Radio Rx Power Low Alarm is enabed

Fault Management Procedure

XPD(Vertical) and XPD(Horizontal) should measure between [29 ÷ 35 dB] by tuning the OMT Coupler

In case of failure in one polarization, the FMP disable automatically the remote polarization. Press the button “Reset Procedure” to turn On XPIC.

Vertical

Vertical

TX=ON & RX=ON

TX=ON & RX=ON

Horizontal

Horizontal

FAILURE

TX=OFF & RX=OFF

Local

Remote NEW FW 1.2.0

Synchronisation Priority or Quality Web LCT: Main Menu – Synchronisation

SETS is a hardware circuit that select the source interface of synch in base at priority or it can switch the source according with quality.

Manual Operation

1

After this period the alarm apears Wait time to restore

After this period the alarm disapears Enable SSM G.8264 (Quality of Synch)

Free Running = missing source synch, an auto Internal synch is generated by itself (PLL). Holdover = degrade of Synch, trying to recover. Locked = normal situation of STM1 synchronisation of status control.

Synchronisation Source 2

4

1 Disable High

Manual reset (Wait to Restore)

Status Alarms is generated by: - LTI (Loss of timing input) - Drift (Bad quality)

3

set priority to define source of synch

Manual Operation Forced by Operator The SSM feature must be always enabled on Radio Interfaces

Low

ITU-T G.8261 SyncE availables on all interfaces

Synchronism direction : Slave = the interface is input of SyncE Master = the interface is output of SyncE Auto = According to synch direction NEW FW 1.1.0

PTP 1588

1588v2 Precision Timing Protocol (Telecom Profile - Boundary Clock) ITU T 8275.1 Profiles (T-BC): ITU-T (T BC): hop by hop boundary clock

NEW FW 1.1.31

Ethernet Switch Functionalities DATA PLANE (QoS) •Physical layer management  Speed/Duplex (AUTO, 10/100/1000/2.5G/10G)  Autonegotiation  Cable Crossover (AUTO/MDI/MDIX)  SFP diagnostic •Ingress Filtering  MTU size  ACL  Rate Limiter •Service Instance Mapping  C-VID management (VLAN 802.1q)  S-VID management (QinQ 802.1ad)  EVC management (MEF 10.3) •Classification Criteria  Priority per port  Priority per PCP [VLAN (802.1p)]  Priority per DSCP [IP Type of Service]  Priority MPLS EXP bits  Output Priority remapping •Metering & Ingress policing MEF Bandwidth profile CIR,EIR,CBS,EBS Based on UNI or EVC or COS •Ingress Manipulation •Learning & Forwarding •Queue depth •Congestion Avoidance  Tail, WRED •Scheduling  Strict Priority, Weighted Round Robin and Mixed  H-QoS •Segress Shaping

CONTROLL PLANE •Layer 2 Control Protocol •Header Ethernet Compression •Traffic isolation per port •Traffic mirroring per port •Ethernet Line Protection (ELP) •IEEE 802.3ad Link Aggregation (LACP) •IEEE 802.1d/ 802.1w STP / RSTP •Link Loss Forwarding •IEEE 802.1ab Link Layer Discovery Protocol (LLDP) •LAN Statistic RFC1213 - RFC1234 •RMON RFC2819 counter History  Per port  Per Service (CVLAN, SVLAN)  Per Priority  Per Queue •ETH CFM OAM (IEEE802.1ag/ITU-T Y.1731) •ITU-T G.8264 SyncEth Quality mngt (SSM ) •1588 Precision Timing Protocol (T - BC) •MAB Microwave Adaptative Bandwidth - CISCO

NEW FW 1.4.0

TAG composition Untagged packet [Ethernet Frame]

Tagged packet (C-Tag) [802.1Q Tagged Frame]

Tagged packet (S-Tag) [802.1ad Double Tagged Frame]

VLAN Paths used to create: • E-Line (point to point services) • E-LAN (multipoint services)

The value of S_Tag TPID can be changed using CLI

UNI

UNI

Vlan 10,11

Vlan 11, 12 Vlan 11, 12, 13

Vlan 10, 11, 12, 13, 14

LAN B

LAN A

NNI NNI Trunk port

UNI = User - Network Interface or Access NNI = Network to Network Interface

Vlan 11,14

UNI

Access port Vlan 11, 13

UNI

Bridge Mode Configuration

Traffic affective and automatic software restart

Command

Purpose

SM-OS# c t ; bridge-mode customer

#Enable Customer Bridge (802.1q) [untag and C-VLAN frames]

SM-OS# c t ; bridge-mode provider-core

#Enable Provider Core Bridge (802.1ad) [S-VLAN frame only]

SM-OS# c t ; bridge-mode provider-edge

#Enable Provider Edge Bridge [untag, C-VLAN and S-VLAN frames]

Bridge Port Type Customer Bridge CBP XGLAN Ex 0/1

CBP LAN2 Gi 0/3

LAN3 Gi 0/6

Switch

CBP TRX Ex 0/2

TPID:0x8100

Provider Edge Bridge Provider Core Bridge CNP XGLAN Ex 0/1

CEP LAN2 Gi 0/3

MNGT Gi-0/7

TRX Ex 0/2

Switch

PNP

LAN3 PNP Gi 0/6

XGLAN Ex 0/1

Switch

PNP

TPID:0x88a8 Untag to Tag

LAN2 Gi 0/3

TPID:0x88a8

MNGT Gi-0/7

Customer Network (802.1Q [C_Tag]) UnTag UnTag PVid based C-Tag Tag C-Tag C-Tag C-Tag Bridge Mode

LAN3 PNP Gi 0/6

MNGT Gi-0/7

Transport Network (802.1ad [S_Tag] )

S Tag S-Tag

CNP (PortVid based)

S Tag S-Tag

S-Tag

CEP (C-VLAN based) [MEF10.2]

S-Tag

Ports Type allowed

CB = Customer Bridge

CBP = Customer Bridge Port (default setting)

PEB = Provider Edge Bridge

CEP = Customer Edge Port CNP = Customer Network Port PNP = Provider Network Port (default setting) pPNP = proprietary Provider Network Port

PCB = Provider core Bridge

PNP = Provider Network Port (default setting) pPNP = proprietaryProvider Network Port

TRX Ex 0/2

Bridge Port Type Command

Purpose

SM-OS# c t ; interface ex 0/1 SM-OS(config-if)# bridge port-type customerBridgePort

#Set XGLAN = CBP (Available only for CB mode )

SM-OS# c t ; interface ex 0/1 SM-OS(config-if)# bridge port-type customerEdgePort

#Set XGLAN = CEP (Available only for PEB mode)

SM-OS# c t ; interface ex 0/1 SM-OS(config-if)# bridge port-type customerNetworkPort port-based

#Set XGLAN = CNP (Available only for PEB mode)

SM-OS# c t ; interface ex 0/1 SM-OS(config-if)# bridge port-type propProviderNetworkPort

#Set XGLAN = pPNP (Available only for PEB and PCB mode)

SM-OS# c t ; interface ex 0/1 SM-OS(config-if)# bridge port-type providerNetworkPort

#Set XGLAN = PNP (Available only for PEB and PCB mode)

Example 7 SM-OS# show interface bridge port-type MNGT TRX LAN4 Not Used LAN2 Not Used LAN4 XGLAN

Gi0/7 Bridge port type is Prop Provider Network Port Ex0/2 Bridge port type is Provider Network Port Gi0/1 Bridge port type is Customer Network Port(Port-Based) Gi0/2 Bridge port type is Provider Network Port Gi0/3 Bridge port type is Provider Network Port Gi0/4 Bridge port type is Provider Network Port Gi0/5 Bridge port type is Provider Network Port Gi0/6 Bridge port type is Customer Network Port(Port-Based) Ex0/1 Bridge port type is Customer Network Port(Port-Based) Gi0/8 Bridge port type is Provider Network Port SM-OS#

Bridge Mode/ Bridge Port Type behavior Bridge Mode/Port Type Customer Bridge/ Customer Bridge port

Provider Edge Bridge/ Customer Network Port

Acceptable Frame Types

Provider Edge Bridge/ Provider Network Port

Provider Edge Bridge/ Provider Network Port (Proprietary)

Provider core Bridge/ Provider Network Port

Provider core Bridge/ Provider Network Port (Proprietary)

The incoming C-Tagged (8100) frame

The incoming S-Tagged (88a8) frame

All

C-tagged into the switch with the pvid of interface

Must be declared into the VLAN table

C-tagged into the switch with the pvid of interface

Tagged

Deleted

Must be declared into the VLAN table

Deleted

UnTagged and Priority Tagged

C-tagged into the switch with the pvid of interface

Deleted

C-tagged into the switch with the pvid of interface

All

Not allowed

Tagged

Not allowed

UnTagged and Priority Tagged Provider Edge Bridge/ Customer Edge Port

The incoming Untagged frame are

S-tagged into the switch with the pvid of interface

S-tagged into the switch with the pvid of interface

All

Not allowed

Tagged

Not allowed

(88a8) is deleted and (9100) is S-tagged into the switch with the pvid of interface

UnTagged and Priority Tagged

S-tagged into the switch with the pvid of interface

Must be mapped the EVC

S-tagged into the switch with the pvid of interface

All

Deleted

S-tagged into the switch with the pvid of interface

Must be declared into the VLAN table and (9100) is S-tagged into the switch with the pvid of interface

Tagged

Deleted

Deleted

Must be declared into the VLAN table

UnTagged and Priority Tagged

Deleted

S-tagged into the switch with the pvid of interface

(88a8) is deleted and (9100) is S-tagged into the switch with the pvid of interface

All

C-tagged into the switch with the pvid of interface

Must be declared into the VLAN table

C-tagged into the switch with the pvid of interface

Tagged

Deleted

Must be declared into the VLAN table

Deleted

UnTagged and Priority Tagged

C-tagged into the switch with the pvid of interface

Deleted

C-tagged into the switch with the pvid of interface

All

Deleted

S-tagged into the switch with the pvid of interface

Must be declared into the VLAN table

Tagged

Deleted

Deleted

Must be declared into the VLAN table

UnTagged and Priority Tagged

Deleted

S-tagged into the switch with the pvid of interface

(88a8) is deleted and (9100) is S-tagged into the switch with the pvid of interface

All

C-tagged into the switch with the pvid of interface

Must be declared into the VLAN table

C-tagged into the switch with the pvid of interface

Tagged

Deleted

Must be declared into the VLAN table

Deleted

UnTagged and Priority Tagged

C-tagged into the switch with the pvid of interface

Deleted

C-tagged into the switch with the pvid of interface

Port Manager: Interface & Status Change value parameters when interface is disabled

Press over there to change status

= Autonegotiation Disable

Up = port Enable Down = port Disable

= Autonegotiation Enable

Status SFP Module only

... or using CLI show interfaces status show interfaces description show interface bridge port-type show inteface mtu show flow-control

SFP mono fiber management is supported NEW FW 1.1.0

Port Manager: Interface & Status Command

Purpose

SM-OS(config-if)# duplex auto

#Enable Autonegotiation: duplex auto or negotiation or speed auto

SM-OS(config-if)# no negotiation; duplex half

#Enable Half duplex

SM-OS(config-if)# no negotiation; duplex full

#Enable Full duplex

SM-OS(config-if)# speed nonegotiate

The speed of the interface can be: speed nonegotiate = Disable negotiation on the port speed auto = automatically detect speed 10 = Port runs at 10Mbps speed 100 = Port runs at 100Mbps speed 1000 = Port runs at 1000Mbps speed 2500 = Port runs at 2500Mbps speed 10000 = Port runs at 10Gbps (TRX, XGLAN)

SM-OS(config-if)# mdix auto

Enable Auto Cross over of the interface

SM-OS(config-if)# no mdix auto; set port mdi

Sets the port to mdi mode. This is hardware specific where transmit pair are pins 1,2 and the receive pair are 3,6 pins

SM-OS(config-if)# no mdix auto; set port mdix

Sets the port to mdix mode. This is hardware specific where transmit pair are pins 3, 6 and the receive pair are 1, 2 pins

SM-OS(config-if)# shutdown; mtu 1500; no shutdown;

The MTU size from 46Byte up to 12266Byte

SM-OS(config-if)# shutdown;flowcontrol send off; flowcontrol receive off; no shutdown;

Flowcontrol value for an interface flowcontrol send on flowcontrol send off flowcontrol receive on flowcontrol receive off

NEW FW 1.1.0

CLI: show interfaces status SM-OS# show interfaces status Port ---Gi0/7 Ex0/2 Gi0/1 Gi0/2 Gi0/3 Gi0/4 Gi0/5 Gi0/6 Ex0/1 Gi0/8 SM-OS#

Status -----connected connected not connected not connected not connected not connected not connected not connected not connected not connected

Duplex -----Full Full Half Full Full Full Full Half Full Full

Speed ----100 Mbps 10 Gbps 1 Gbps 1 Gbps 1 Gbps 1 Gbps 10 Gbps 1 Gbps

Negotiation ----------Auto No-Negotiation Auto Auto No-Negotiation Auto Auto Auto No-Negotiation Auto

Capability ---------Auto Auto Auto Auto Auto Auto Auto Auto Auto Auto

Packets are loopback Command

Purpose

SM-OS(config-if)# shutdown

#Disable Interface

SM-OS(config-if)# no shutdown

#Enable Interface

SM-OS(config-if)# no shutdown; loopback local

#Enable line loop (depending on Timeout value)

SM-OS(config-if)# no loopback local; shutdown;

#Disable line loop

SM-OS(config-if)# media-type

#Change media type for combo interface : copper = RJ45 SFP fiber = LC SFP

SM-OS# snmpwalk mib oid 1.3.6.1.2.1.2.2.1.6

#Show ifPhysAddress (MAC addresses of switch interfaces)

Rate Limiting or Storming control 0 = it means disabled

Destination Lookup Failure (Unknown Unicast packet)

Egress Rate Limit (0=disable)

Packet per second

NEW FW 1.1.0

Rate Limiting or Storming control ... using CLI Command

Purpose

SM-OS(config-if)# storm-control level

#Enable Ingress rate limiter on interface

broadcast dlf multicast frame per second from 1 = Disable to 2147483647

SM-OS(config-if)# no storm-control broadcast level SM-OS(config-if)# no storm-control dlf level SM-OS(config-if)# no storm-control multicast level

#Disable Ingress rate limiter on interface

SM-OS# show interfaces storm-control

#show storm control for any interfaces.

SM-OS(config-if)# rate-limit output rate-value burst-value

#Enable Egress rate limiter on interface = Kbit/s value from 1 to 80000000. = Kbit value from 1 to 80000000.

SM-OS(config-if)# no rate-limit output

#Disable Egress rate limiter on interface

SM-OS# show interfaces rate-limit

#show rate limit for any interfaces.

NEW FW 1.1.0

Internal Priority Assignment Press over

Priority classification: 7 - Network control 6 - Voice (latency ≤ 10msec) 5 - Video (latency ≤ 100msec) 4 - Controlled load 3 - Excellent load 2 - Standard (spare traffic). 1 - Background. 0 - Best effort

PCP = Priority Code Point (IEEE 802.1p) Class of Service (VLAN - data link layer L2)

NEW FW 1.1.0

Internal Priority Assignment DSCP = Differentiated Services - Type of Service (IP - network layer L3)

Press over

DSCP classification: CS7 - Network control CS6 - Internetwork Control CS5,EF - Critic/ECP CS4, AF41-43 - Flash Override CS3, AF31-33 - Flash CS2, AF21-23 - Immediate CS1, AF11-13 - Priority CS0 - Routine (Best effort) NEW FW 1.1.0

Internal Priority Assignment ... using CLI

Command

Purpose

SM-OS(config-if)# qos pbit-preference

#change priority management of interface: enable = Native 802.1p (PCP) Layer 2 disable = Native DSCP Layer 3

SM-OS# c t; priority-map SM-OS(config-pri-map)# map interface ex 0/1 in-priority-type vlanPri in-priority regen-priority

#add priority map index : = index value from 9 to 65535. in-priority-type : vlanPri - 802.1p value from 0 to 7. ipTos - priority value from 0 to 7. ipDscp - priority value from 0 to 63. mplsExp - priority value from 0 to 7. vlanDEI - priority value from 0 to 1.

SM-OS# c t ;no priority-map ;end

#delete priority map index: = from 9 to 65535.

SM-OS# show priority-map

#show priority map index.

SM-OS# show qos pbit-preference-over-dscp

#show priority preference: enabled = PCP (ClassOf Service L2) disabled = DSCP (Type Of Service L3)

PriorityMapId

IfIndex

VlanId

InPriorityType

InPriority

RegenPriority

InnerRegenPriority

1

0

0

VlanPriorty

0

0

None

2

0

0

VlanPriorty

1

1

None

3

0

0

VlanPriorty

2

2

None

4

0

0

VlanPriorty

3

3

None

5

0

0

VlanPriorty

4

4

None

6

0

0

VlanPriorty

5

5

None

7

0

0

VlanPriorty

6

6

None

8

0

0

VlanPriorty

7

7

None

Default factory configuration

Ingress Filter - Access Control List 3

2 Based on VLAN/Priority

1 ... using CLI Example (Classification based on MPLS) #create an ACL with ID 1007 for traffic mpls exp bit = 7 mac access-list extended 1007 permit any any mpls-exp 7 exit #Active the filter on XGLAN1 ex 0/1 interface ex 0/1 mac access-group 1007 in exit #create a new classification based on ACL 1007 that assign priority 7 class-map 1007 match access-group mac-access-list 1007 set class 1007 regen-priority 7 group-name class1007 exit

Based on source Mac Address Based on MPLS

Deny/Permit

5

4

NEW FW 1.1.0

Access Control List Command

... using CLI

Purpose

SM-OS(config)# mac access-list extended SM-OS(config-ext-macl)# SM-OS(config-ext-macl)# exit SM-OS(config)#

#create an ACL with ID in order to filter traffic: = index value from 1 to 65535. #Filter action: = deny or permit traffic #based on MAC Address = any or host xx:xx:xx:xx:xx:xx Src MAC = any or host xx:xx:xx:xx:xx:xx Dst MAC #based on rule : vlan - 802.1q value from 1 to 4094 Priority - Priority value 1=low and 255=high svlan id - 802.1ad value from 1 to 4094 svlan-id cvlan-priority - 802.1p value from 0 to 7 svlan-priority - 802.1p value from 0 to 7 single-tag or double-tag vlan tagged packets ip-over-mpls ip-type ipv4 dscp value from 0 to 63 mpls-exp - 802.1p value from 0 to 7

SM-OS(config)# interface ex 0/1 SM-OS(config-if)# mac access-group in SM-OS(config-if)# exit

#Active the filter on XGLAN1 ex 0/1 with ID : = index value from 1 to 65535. #direction: in = Inbound packet

SM-OS# show access-lists

#Show all the ACL L2 and L3

EVC S-VID Based COS S-VID + Priority Based

Metering – Policing EVC1 EVC1

EVC C-VID Based COS C-VID + Priority Based

Bandwidth profile

Priority Based

EVC2

UNI

EVC2 EVC3

EVC3

2 1 Two Rate Three Color Marker metering as defined by RFC 2698

3

4

CIR – Committed Information Rate [0 ÷ 10485760 Kbit/s] CBS – Committed Burst Size [0 ÷ 10485760 Kbit] EIR – Excess Information Rate PIR – Peak Information Rate [0 ÷ 10485760 Kbit/s] EBS – Excess Burst Size [0 ÷ 10485760 Kbit] NEW FW 1.1.0

CLASS MAP ... using CLI

Command

Purpose

SM-OS(config)# class-map SM-OS(config-cls-map)# match access-group SM-OS(config-cls-map)# set class SM-OS(config-cls-map)# exit SM-OS(config)#

#create a new classification with ID : = index value from 9 to 65535. #Performs matching operation on : mac-access-list - based on ACL L2 ip-access-list - based on ACL L3 priority-map - based on priority-map vlan-map - based on vlan-map = ID value to recall from 1 to 65535. #Set Class with ID : = index value from 1 to 65535. #optionally configure the parameters Pre-color = green or yellow or red or none regen-priority group-name = internally classify with the new priority yellow-dei-bit-set = 0 or 1 bit DEI VLAN field

SM-OS# show class-map

#Show all the class map entry

ClassMapId

L2FilterId

L3FilterId

PriorityMapId

Yellow-dei-bit

CLASS

PolicyMapId

PreColor

Status

1

None

None

1

None

1

1

None

Active

2

None

None

2

None

1

1

None

Active

3

None

None

3

None

1

1

None

Active

4

None

None

4

None

1

1

None

Active

5

None

None

5

None

1

1

None

Active

6

None

None

6

None

1

1

None

Active

7

None

None

7

None

1

1

None

Active

8

None

None

8

None

1

1

None

Active

METER and POLICY MAP Command

... using CLI

Purpose

SM-OS(config)# meter SM-OS(config-meter)# meter-type trTCM cir cbs pir ebs SM-OS(config-meter)# exit SM-OS(config)#

#create a new meter with ID : = index value from 1 to 65535. #Two rate three color marker (RFC 2697) #Set value in Kbit/s: - CIR value from 0 to 10485760. - CBS value from 0 to 10485760. - PIR=EIR+CIR value from 0 to 10485760. - EBS value from 0 to 10485760.

SM-OS# show meter

#Show all the class map entry

SM-OS(config)# policy-map SM-OS(config-ply-map)# set meter SM-OS(config-ply-map)# set policy class SM-OS(config-ply-map)# exit SM-OS(config)#

#create a new policy map with ID : = index value from 2 to 65535. #define the meter id already created : - ID value to recall from 1 to 65535. #Configure : violate-action drop exceed-action cos-transmit-set #define as policy the class-map id already created : - ID value to recall from 0 to 65535.

SM-OS# show meter

#Show all the class map entry

Queue & Scheduling Strict Priority: the queue with highest priority is completely emptied before sending frame of the queue with lower priority. WRR (Weighted Round Robin): based on the weight criteria defined by the user [1÷127 packets].

Example (scheduler) config terminal scheduler 1 interface ex 0/2 sched-algo wrr queue 1 interface ex 0/2 qtype 1 weight 4 queue 2 interface ex 0/2 qtype 1 weight 32 queue 3 interface ex 0/2 qtype 1 weight 64 queue 4 interface ex 0/2 qtype 1 weight 0 queue 5 interface ex 0/2 qtype 1 weight 0 queue 6 interface ex 0/2 qtype 1 weight 0 queue 7 interface ex 0/2 qtype 1 weight 0 queue 8 interface ex 0/2 qtype 1 weight 0

Drop Type: criterion by which packets are discarded within a queue that is filled: • Tail: When the queue is full then the last packet is deleted. • WRed: Weighted Random Early Detection.

NEW FW 1.1.0

Queue & Scheduling Command

... using CLI

Purpose

SM-OS(config)# queue-type SM-OS(config-qtype)# set algo-type queue-drop-algo

ONLY for WRED SM-OS(config-qtype)# random-detect dp

#create queue template: = index value from 1 to 65535. = tailDrop or wred congestion avoidance = enable or disable drop algorithm = Drop precedence value: 0 – low drop precedence [Discard TCP Green] 1 – medium drop precedence [Discard TCP Yellow] 2 – high drop precendece [Discard TCP Red] 3 – non-TCP Green 4 – non-TCP Yellow 5 – non-TCP Red

SM-OS(config)# queue interface qtype weight shaper

#modify queue template: = 1 to 8 used by default. From 9 to 65535 must be mapped. = switch port (e.g gi 0/1). = queue template index. = weight from 0 (strict-priority) to 127 = shaper template index.

SM-OS(config)# scheduler 1 interface sched-algo

#modify scheduler algorithm: = switch port (e.g. gi 0/1). = strict-priority or wrr

SM-OS(config)# shape-template cir pir

#create a shaper template per queue: = index value from 1 to 65535. = Kbit/s value from 1 to 10485760. = Kbit/s value from 1 to 10485760.

SM-OS# show queue; show scheduler

#show the queues & scheduler config.

Layer 2 Control protocol It doesn’t work in Provider Core Bridge mode

When protocol tunneling is enabled, edge switches on the inbound side of the service-provider network encapsulate Layer 2 protocol packets with a special MAC address and send them across the service-provider network. Core switches in the network do not process these packets but forward them as normal packets.You can enable Layer 2 protocol tunneling (by protocol) on the ports that are connected to the customer in the edge switches of the service-provider network. ... or using CLI

show l2protocol-tunnel summary show l2protocol tunnel-mac-address

NEW FW 1.1.0

Layer 2 Control protocol Command

Purpose

SM-OS(config-if)# l2protocol-tunnel

#Enabled tunneling of L2 protocol (the packets pass unchanged)

SM-OS(config-if)# l2protocol-peer

#Enabled peering of L2 protocol (the packets end in the switch)

SM-OS(config-if)# l2protocol-discard

#Discard L2 protocol (the packets are dropped)

SM-OS(config)# l2transparent-tunnel

#Transparent tunneling for each interfaces of switch : = enable or disable

SM-OS(config)# l2protocol-tunnel cos

#change default priority for layer2 protocol tunneled: = priority value from 0 to 7.

PROTOCOL Dot1x =802.1X access control and authentication protocol LACP = link aggregation control protocol PDUs STP = spanning tree protocol BPDUs GVRP = Generic VLAN Registration Protocol BPDUs GMRP = Garp Multicast Registration Protocol BPDUs IGMP = Internet Group Multicast Protocol MVRP= Multiple VLAN Registration Protocol MMRP=Multiple MAC Registration Protocol LLDP = Link Layer Discovery Protocol

Example 9 protocol pass transparent ct #XGLAN configuration interface ex 0/1 l2protocol-tunnel dot1x ; l2protocol-tunnel lacp ; l2protocol-tunnel stp l2protocol-tunnel gvrp ; l2protocol-tunnel gmrp ; l2protocol-tunnel igmp l2protocol-tunnel mvrp ; l2protocol-tunnel mmrp ; l2protocol-tunnel lldp exit

VLAN: Basic Settings MAC table stored on VLAN index MAC Learning disable

Don’t change the PVID of MNGT from this menu . Please use DCN MNGT Port Configuration 802.1p: From 0 up to 7 assigned to untagged packets arriving at the port Port Vlan ID: from 1 up to 4094 (factory default VID=1) Ingress Filtering: •Enabled = The tagged frame is discarded if this port is not a member of the VLAN . •Disabled = All frames are forwarded in accordance with the 802.1Q VLAN table although the interface is not a member of VLAN. •All frame types are accepted at ingress (tagged and untagged) •Only tagged frames present in the VLAN table •Only Untagged frames and frame with VID=0

VLAN: Basic Settings Command

Purpose

SM-OS(config-if)# switchport acceptable-frame-type

#Configure the ingress filtering : all = acceptable all type of frame tagged = The untagged and priority tagged frames received on the port are rejected. untaggedAndPrioritytagged = The tagged frames received on the port are rejected.

SM-OS(config-if)# switchport ingress-filter

#Enable ingress filtering feature [ Recommended always enabled]: Not allows undesired traffic enter into the switch

SM-OS(config-if)# no switchport ingress-filter

#Disable ingress filtering feature

SM OS(config if)# switchport pvid SM-OS(config-if)#

#change PortVlanID default: = 802.1q value from 1 to 4094. (Need interface member port of VLAN )

SM-OS(config-if)# switchport priority default

#change port priority default: = 802.1p value from 0 to 7.

SM-OS(config)# mac-address-table aging-time

#change MAC Address Table Aging time: = value from 10 to 1000000 seconds.

SM-OS(config)# clear mac-address-table dynamic

#Clear MAC Address Table

show vlan learning params ... or using CLI show mac-address-table show mac-address-table count show mac-address-table aging-time

VLAN: Static VLANs declare which interfaces belong at the VLAN (internal forwarding).

VLAN Range

declare which interfaces member remove the VLAN in output of the switch.

• the VLAN packet is forwarded in each Member Ports keeping the original VLAN • the VLAN packet is forwarded in each Untagged Ports removing the original VLAN

0x8100, VLAN tagged frame (IEEE 802.1q ) 0x88A8, Provider Bridging (IEEE 802.1ad)

VLAN: Static VLANs Command

Purpose

SM-OS(config)# vlan

#Create/Modify VLAN = 802.1q value from 1 to 4094.

SM-OS(config)# no vlan

#Delete VLAN = 802.1q value from 1 to 4094.

SM-OS(config-vlan)# ports name

#VLAN member port : ex 0/1 = XGLAN ex 0/2 = TRX gi 0/3 = LAN2 gi 0/6 = LAN3 gi 0/1 = LAN4 = VLAN name

SM-OS(config-vlan)# ports add

#Add VLAN member port

SM-OS(config-vlan)# ports untagged

#Add VLAN untagged member port

SM-OS(config-vlan)# no ports

#Remove all ports VLAN’s member

SM-OS(config-vlan)# vlan egress ether-type

#Change VLAN Ether-Type : CTAG = 0x8100 QINQ = 0x9100 STAG = 0x88A8

... or using CLI show vlan show vlan port config port gigabitethernet 0/1 show vlan device info show service vlan show service vlan mapping

Ingress/Egress EtherType Filter It’s availabled in Provider Edge Bridge and Provider Core Bridge

Ingress = traffic entering the switch Egress = traffic coming out of the switch

Bridge Port type

Default EtherType Ingress

Egress

CNP

0x88A8

0x88A8

CEP

0x88A8

0x8100

PNP

0x88A8

0x88A8

pPNP

0x8100

0x8100

Command SM-OS(config-if)# switchport dot1q ether-type

Descriptions

S VLAN cannot enter or exit from this port S-VLAN

S-VLAN can enter or exit from this port

Purpose #Configure the filter : ingress = into the switch egress = out of the switch #Ether-Type : = TPID value from 1 to 65535 decimal. C-VLAN = 33024 decimal [0x8100 hexadecimal] S-VLAN = 34984 decimal [0x88a8 hexadecimal] S-VLAN = 37120 decimal [0x9100 hexadecimal]

C-VLAN Rewriting It’s availabled in Provider Edge Bridge only

LAN PNP 10

PEB

PEB

110

Radio PNP PNP 110

110

LAN PNP 110

20

120

120

120

120

30

130

130

130

130

Bridge Port type

EtherType Ingress

PNP

0x8100

Bridge Port type

Egress 0x8100

EtherType Ingress

PNP

0x8100

Egress 0x8100

SM-OS# show vlan learning params

CLI: show vlan

Unicast MAC Learning Parameters ------------------------------------Vlan Id : 127 Mac Learning Admin-Status : Default Mac Learning Oper-Status : Enable Mac Learning Limit : 100 ------------------------------------SM-OS#

SM-OS# show vlan port config port ex 0/1 Vlan Port configuration table ------------------------------Port Ex0/1 Bridge Port Type : Customer Network Port(Port-Based) Port Vlan ID : 1 Port Acceptable Frame Type : Admit Only Untagged and Priority Tagged Port Mac Learning Status : Enabled Port Ingress Filtering : Enabled Port Mode : Access Port Gvrp Status : Disabled Port Gmrp Status : Disabled Port Gvrp Failed Registrations : 2 Gvrp last pdu origin : 00:00:00:00:00:00 Port Restricted Vlan Registration : Disabled Port Restricted Group Registration : Unknown Mac Based Support : Disabled Subnet Based Support : Disabled Port-and-Protocol Based Support : Enabled Default Priority : 0 Filtering Utility Criteria : Default Port Protected Status : Disabled Ingress EtherType : 0x88a8 Egress EtherType : 0x88a8 Egress TPID Type : Portbased Allowable TPID 1 : 0x0 Allowable TPID 2 : 0x0 Allowable TPID 3 : 0x0 ------------------------------------------------------SM-OS#

SM-OS# show vlan Vlan database ------------Vlan ID : 127 Member Ports : Gi0/7, Ex0/2 Untagged Ports : Gi0/7 Forbidden Ports : None Name : Status : Permanent Egress Ethertype : 0x88a8 ServiceType : E-LAN MacLearning Admin-Status : Default MacLearning Oper-Status : Enabled Service Loopback Status : Disabled ---------------------------------------------------SM-OS# SM-OS# show vlan device info Vlan device configurations -------------------------Vlan Status Vlan Oper status Gvrp status Gmrp status Gvrp Oper status Gmrp Oper status Mac-Vlan Status Subnet-Vlan Status Protocol-Vlan Status Bridge Mode Base-Bridge Mode Traffic Classes Vlan Operational Learning Mode Hybrid Default Learning Mode Version number Max Vlan id Max supported vlans Global mac learning status Filtering Utility Criteria Unicast mac learning limit Inner Tpid SM-OS#

: : : : : : : : : : : : : : : : : : : : :

Enabled Enabled Disabled Disabled Disabled Disabled Disabled Disabled Enabled Provider Edge Bridge Vlan Aware Bridge Enabled IVL IVL 1 4094 256 Enabled Enabled 16000 0x8100

Ethernet Switch Scenario • SCENARIO 1 - Customer Bridge [ Trunk (Ctag) – Access Link (Untag) ] • SCENARIO 2 - Customer Bridge [ Trunk (Ctag) – Trunk (Ctag) ] • SCENARIO 3 - Provider Edge Bridge [ Trunk (Stag) – Access Link (Ctag) ] • SCENARIO 4 - Provider Edge Bridge [ create EVC (Stag) ] • SCENARIO 5 - Provider Edge Bridge [ create EVC (Stag) ] • SCENARIO 6 - Provider Edge Bridge [ VLAN Split ]

Scenario#1

Trunk configure terminal bridge mode customer bridge-mode # LAN 1 interface switchport ingress-filter no shutdown exit # RADIO interface switchport ingress-filter no shutdown exit # TAGGED XGLAN RADIO vlan 10 ports end

Trunk configure terminal bridge mode customer bridge-mode # RADIO UNTAGGED XGLAN vlan 10 ports untagged exit # LAN 1 interface switchport pvid 10 ; switchport priority default 7 switchport ingress-filter ; no shutdown ; exit # RADIO interface switchport ingress-filter ; no shutdown ; exit end

Scenario#2

Trunk configure terminal bridge mode customer bridge-mode # LAN 1 interface switchport ingress-filter no shutdown exit # RADIO interface switchport ingress-filter no shutdown exit # TAGGED XGLAN RADIO vlan 10 ports end

Access configure terminal bridge mode customer bridge-mode # LAN 1 interface switchport ingress-filter no shutdown exit # RADIO interface switchport ingress-filter no shutdown exit # TAGGED XGLAN RADIO vlan 10 ports end

Scenario#3

Trunk configure terminal bridge mode provider-core bridge-mode provider core # XGLAN interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown ; exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter ; no shutdown exit # XGLAN RADIO vlan 100 ports end

Access configure terminal bridge mode provider-edge bridge-mode provider edge # RADIO UNTAGGED XGLAN vlan 100 ; ports untagged exit # XGLAN interface bridge port-type customerNetworkPort port-based switchport svlan-priotype fixed 2 #Copy incoming CVLAN Priority as SVLAN Priority #switchport svlan-priotype copy switchport ingress-filter ; switchport pvid 100 no shutdown ; exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter ; no shutdown ; exit

Scenario#4

Site 1 Site 1 - 3G traffic Site 2 - 3G traffic 3G traffic port 4G traffic port Site 1 - 4G traffic Site 2 - 4G traffic

3G NodeB 4G NodeB Site 2 3G NodeB 4G NodeB

configure terminal bridge-mode bridge mode provider provider-edge edge # LAN 1 interface ; bridge port-type customeredgePort switchport customer-vlan 10 svlan-priotype fixed 3 switchport ingress-filter ; no shutdown ;exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter ; no shutdown ; exit # XGLAN RADIO # XGLAN RADIO vlan 100 ; ports untagged

ethernet evc id evc100 ethernet evc type point-to-Point ; exit vlan 200 ports untagged ethernet evc id evc200 ethernet evc type point-to-Point ; exit #TAGGED LAN 1 interface ethernet uni id UNI01 ethernet map ce vlan 10 evc 100

configure terminal bridge-mode bridge mode provider provider-core core # LAN 1 interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown exit # S-VLAN 100 # S-VLAN 200 vlan 100 ports exit vlan 200 ports end

configure terminal bridge-mode bridge mode provider provider-edge edge # RADIOUNTAGGED XGLAN # RADIOUNTAGGED LAN2 vlan 100 ports untagged ; exit vlan200 ports untagged ; exit # LAN 1 interface bridge port-type customerNetworkPort port-based switchport svlan-priotype copy switchport pvid 100 switchport ingress-filter ; no shutdown ; exit # LAN 2 interface bridge port-type customerNetworkPort port-based switchport svlan-priotype copy switchport pvid 200 switchport ingress-filter ; no shutdown ; exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter ; no shutdown ; exit

Scenario#5

NodeB NodeB

NodeB NodeB

Transport

configure terminal bridge-mode provider-edge # UNTAGGED XGLAN RADIO vlan 100 ports untagged ethernet evc id evc100 ethernet evc type point-to-Point ; exit # C-TAGGED XGLAN interface bridge port-type customeredgePort ethernet uni id UNI01 ethernet map ce-vlan 10 evc 100 switchport customer-vlan 10 svlan-priotype fixed 3 switchport ingress-filter ; no shutdown ; exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown exit

Transport

configure terminal bridge-mode provider-core # S-VLAN 100 vlan 100 ports ethernet evc id evc100 ethernet evc type point-to-Point end # LAN 1 interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown exit

Access

configure terminal bridge-mode provider-edge # LAN 1 interface ; bridge port-type customeredgePort switchport customer-vlan 10 svlan-priotype fixed 3 switchport ingress-filter ; no shutdown ; exit # LAN 2 interface bridge port-type customeredgePort switchport customer-vlan 10 svlan-priotype fixed 3 switchport ingress-filter ; no shutdown ; exit # RADIO interface ; bridge port-type providerNetworkPort switchport ingress-filter ; no shutdown ;exit # RADIO UNTAGGED XGLAN LAN2 vlan 100 ports untagged ethernet evc id evc100 ; ethernet evc type multipoint-to-multipoint ; exit # C-TAGGED XGLAN interface ethernet uni id UNI01 ; ethernet map ce-vlan 10 evc 100 ; exit # C-TAGGED LAN2 interface ethernet uni id UNI02 ; ethernet map ce-vlan 10 evc 100 ; end

Scenario#6

NE NE

NE NE

Transport

Access

Transport

configure terminal bridge mode provider-edge bridge-mode provider edge # UNTAGGED XGLAN RADIO vlan 100 ports untagged exit # LAN 1 interface bridge port-type customerNetworkPort port-based switchport svlan-priotype copy switchport pvid 100 switchport ingress-filter no shutdown exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown end

configure terminal bridge mode provider-core bridge-mode provider # LAN 1 interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter no shutdown exit # S-VLAN 100 vlan 100 ports end

configure terminal bridge mode provider-edge bridge-mode provider edge # RADIO UNTAGGED XGLAN vlan 100 ports untagged

exit # LAN 1 interface bridge port-type customerNetworkPort port-based switchport svlan-priotype copy switchport pvid 100 switchport ingress-filter no shutdown exit # LAN 2 interface bridge port-type customerNetworkPort port-based switchport svlan-priotype copy ; switchport pvid 100 switchport ingress-filter ; no shutdown ; exit # RADIO interface bridge port-type providerNetworkPort switchport ingress-filter ; no shutdown ; exit

Rapid Spanning Tree Parameter used to elect the root bridge

4 3

2 5 1

Life of BPDU Resend BPDU Change Status port

First try to use RSPT, if not available then use standard STP Parameters of packet BPDU (Bridge Protocol Data Unit) used for manage STP/RSTP

Available only in 1+0 radio configuration

8000 = 2.5Gb/s 20000 = 1Gb/s 200000 = 100Mb/s 2000000 = 10 Mb/s

NEW FW 1.4.0

Rapid Spanning Tree Command

Purpose

SM-OS(config)# spanning-tree mode

#Enable STP/RSTP Module : rstp – Enable Rapid Spanning Tree Protocol (802.1w). stp – Enable Spanning Tree Protocol (802.1D).

SM-OS(config)# no spanning-tree mode

#Disable STP/RSTP Module

SM-OS(config)# spanning-tree patchcost

#Configure the patchcost : dynamic = Enable dynamic dynamic lag-speed = Enable dynamic lag-speed

SM-OS(config-if)# spanning-tree

#Enable STP/RSTP in the interface

SM-OS(config-if)# spanning-tree mode dot1w enable

#Enable RSTP interoperability

Alternate Port (Blocked) when bpdu cames from another bridge Backup Port (Blocked) when bpdu cames from the same bridge Bridge Designated Port are in forwarding status ... or using CLI show spanning-tree show spanning-tree active show spanning-tree interface

Available only in 1+0 radio configuration

Bridge

Root Bridge

Root Ports are toward to the Root Bridge

NEW FW 1.4.0

LLF ( Link Loss Forwarding ) "Link Loss Forwarding" is a alarm of malfunction that propagates in the Ethernet link, used in strategies of redirection packets for alternative connections

2

1

3

5 Single => at least one of the selected links is in air loss or removed from RLAG Group => all selected links are in air loss or removed from RLAG

6

In case of radio alarm (demod fail, link id, etc), the LLF is forwarded ( Enable = both sites; Disable = only remote site)

4 Seconds before to generate a LOS alarm

7

The LLF can be forwarded also as a cause of local physical LAN LOS

8 NEW FW 1.1.0

Queue Depth

... or using CLI show queue-template show queue show qos queue-stats interface ex 0/2

Ethernet Line Protection Enable ELP only in one device

13

LAN3

1

80HDX 2

PORT1 active External standby

Switch

LAN4

3

PORT2

8

5 6

4

7 9 10

14 12 11

Not revertible

1. Create a port channel interface 2. Aggregation interfaces with ELP enabled 3. Add port in VLAN table 4. Enable LA Status 5. Enable LAN interfaces

LAG Protocol “Link Aggregation" allows the L2 (based on MAC hashing) or L3 (based on IP hashing) aggregation two or more LANs of the same equipment to one logical channel (Port Channel) and therefore aggregate Ethernet line capacity.

IEEE 802.3ad LAG (Link Aggregation Group) and the relevant protocol LACP (Link Aggregation Control Protocol).

ALFOplus80HDX

Lan1 Lan2

Lan3 Lan4

2Gbps

Po1: 2 Gb/s (LAN3,LAN4)

External Switch

NEW FW 1.1.0

Port Isolation Port Isolation allows easy to separation of client traffic at the VLAN edge. It allows groups of clients to be logically grouped into a single VLAN, but keeps their traffic fenced off so that snooping and tampering can be avoided.

Isolated Port Non-Isolated Port

Example12 Isolated Port LAN3 PVID:100

LAN4 PVID:100

Non-Isolated Port VXGLAN 00

VXGLAN 00

TXR

... or using CLI

configure terminal #LAN3 settings interface gi 0/6 port-isolation ex 0/2 exit #LAN4 settings interface gi 0/1 port-isolation ex 0/2 exit end

NEW FW 1.1.0

Port Mirroring Example13

2

... or using CLI

configure terminal monitor session 1 source interface gi 0/1 both monitor session 1 destination interface gi 0/6 end ; logout

3 4 1 5 6 LAN4

7 TRX

LAN3

Port Mirroring is a method of monitoring network traffic in a switch (copy all network packet seen on one port to another port)

Ethernet sniffer NEW FW 1.1.0

H-QoS (Hierachical Quality Of Service) Hierarchical QoS allows you to specify Qos behavior at multiple policy levels, which provides a high degree of granularity in traffic Management. Up to 4 VLAN/port

Hierarchy Level 2

8 Queues x 5 Schedulers

Hierarchy Level 1

it cannot be changed

0 L1.1 Scheduler 4Service name 8 queues configurable

Scheduler 5Service name 1 L1.2

Scheduler 1 name L0

8 queues configurable 2 L1.3 Scheduler 6Service name

Port scheduler

WFQ

8 queues

Lower

SP

configurable

S

Higher

3 L1.4 Scheduler Service 7 name 8 queues configurable

Scheduler 3

DCN GOLD-L1 name

Scheduler 2 name GOLD-L0 WFQ

8 queues

S

Configurable

Gold Scheduler Classification rules based on PCP (can be configured by operator ) NEW FW 1.0.0

IEEE 802.1ag OAM Ethernet Connectivity Fault Management MEP = Maintenance End Point can generate ccm packets at the edge of Maintenance Domain MIP = Maintenance Intermediate Point respond to received packets ccm.

Ethernet CFM is an end-to-end per-service-instance Operation, Administration and management (OAM) protocol: -IEEE 802.1ag CFM = monitors connectivity of a particular service instance in a given MD (Maintenance Domain). -CCM (Continuity Check Message)= It’s a CFM PDUs generated by MEP to checks Fault detection & Notification -LBM (LoopBack Message) = Test MEP/MIP fault verification -LTM (LinkTrace Message) = path discovery and fault isolation.

NEW FW 1.1.0

IEEE 802.1ag OAM Ethernet Connectivity Fault Management LOCAL

REMOTE

#Create VLAN for the service c t ; Vlan 1112 ; ports ex 0/1 ex 0/2 name OAM1112; exit

#Create VLAN for the service c t; Vlan 1112 ; ports ex 0/1 ex 0/2 name OAM1112; exit

#ECFM IEEE 802.1ag ethernet cfm start ; ethernet cfm enable ; ethernet cfm traceroute cache

#ECFM IEEE 802.1ag ethernet cfm start ; ethernet cfm enable ; ethernet cfm traceroute cache

#Create Domain ethernet cfm domain name SIAE level 7 service name OAM1112 vlan 1112 mep crosscheck mpid 1 vlan 1112 mep crosscheck mpid 2 vlan 1112 set mip-creation-criteria default exit

#Create Domain ethernet cfm domain name SIAE level 7 service name OAM1112 vlan 1112 mep crosscheck mpid 1 vlan 1112 mep crosscheck mpid 2 vlan 1112 set mip-creation-criteria default exit

#Create MEP/ MIP (direction,MEP/MIP ID, VLAN) ##XGLAN interface ex 0/1 no shutdown ; ethernet cfm enable ethernet cfm mep level 7 inward mpid 1 vlan 1112 active exit ;exit ##TRX (RADIO) interface ex 0/2 no shutdown ; ethernet cfm enable ethernet cfm mip level 7 vlan 1112 active exit

#Create MEP/ MIP (direction,MEP/MIP ID, VLAN) ##XGLAN interface ex 0/1 no shutdown ; ethernet cfm enable ethernet cfm mep level 7 inward mpid 2 vlan 1112 active exit ; exit ##TRX (RADIO) interface ex 0/2 no shutdown ; ethernet cfm enable ethernet cfm mip level 7 vlan 1112 active exit

#Active CCM ethernet cfm cc level 7 vlan 1112 interval ten-sec ethernet cfm cc enable level 7 vlan 1112 exit

#Active CCM ethernet cfm cc level 7 vlan 1112 interval ten-sec ethernet cfm cc enable level 7 vlan 1112 exit

#crosscheck MEP/MIP ethernet cfm mep crosscheck enable level 7 vlan 1112

#crosscheck MEP/MIP ethernet cfm mep crosscheck enable level 7 vlan 1112

NEW FW 1.1.0

IEEE 802.1ag OAM Ethernet Connectivity Fault Management #SHOW MEP STATUS UP=OK DOWN=KO show ethernet cfm domain level 7

MEP STATUS

#TEST traceroute based on MAC LTM end sho mac-address-table dynamic unicast vlan 1111 sleep 5 traceroute ethernet mac 00:B0:AC:07:2E:64 level 7 vlan 1111 time-to-live 5

(Loop Trace Message)

#TEST traceroute based on mpid traceroute ethernet mpid 2 level 7 vlan 1111 time-to-live 5 #TEST loopback based on MAC end sho mac-address-table dynamic unicast vlan 1111 sleep 5 ping ethernet mac 00:B0:AC:07:2E:64 level 7 vlan 1111 count 5

LBM (Loop Back Message)

#TEST loopback based on mpid ping ethernet mpid 2 level 7 vlan 1111 count 5 #to disable ECFM configure terminal ; no ethernet cfm start ; end set hitless-restart enable ; sleep 5 Reload

Disable ECFM

NEW FW 1.1.0

802.1ab LLDP (Link Layer Discovery Protocol) •The Link Layer Discovery Protocol (LLDP) is a method to allow networking devices to advertise abilities, identity, and other information into a LAN. •LLDP protocol data units (LLDPDUs) are sent inside Ethernet frames and identified by their destination MAC address and Ethertype (0x88CC).

Example (start and Enable LLDP on the system) admin admin #ENABLE LLDP config terminal no shutdown lldp set lldp enable end logout

Example (disable LLDP) admin admin #DISABLE LLDP config terminal set lldp disable shutdown lldp end logout

NEW FW 1.0.0

Statistics: Interface

... or using CLI

show interfaces counters show ip traffic interface vlan 1

Using WebLCT...

Statistics: Queue enqueued

2

dequeued discarded 1

show qos queue-stat interface ex 0/2

NEW FW 1.1.0

RMON: Settings Ethernet performance monitoring

2

Using WebLCT...

3

1

1÷65535

4 SM-OS# show rmon statistics

6

5

RMON is enabled

... or using CLI

SM-OS# XGLA N 10Gbps

RX TX

RX TX

LAN3

TRX 10Gbps

TX 10.0% = 1000Mbps RX

7

1Gbps

NEW FW 1.1.0

RMON: Ethernet History

Using WebLCT...

3 Utilization(based per Service) = [Sent Octets x (8 bit) ] / Interval (s)

... or using CLI

1 2

show running-config rmon show rmon statistics show rmon history show service statistics show service history

Buckets are the max number of samples collected in the Ethernet Hystory (value between 1 and 240). The equipment stores these data in a circular buffer, where the new information in input overwrites the old one.The recommended maximum value of bucket for all the instances is 2400. Persistence box, the status of automatic storing of RMon statistics on non-volatile memory: • Disable. Automatic storing inactive. • Enable. Automatic storing active. Interval (s) sampling interval used to collect the data of the history: • one of the following values can be set: 60, 300, 600, 900, 1200, 1800 or 3600 seconds. The minimum recommended = 60 sec. NEW FW 1.1.0

RMON: collections Ethernet Statistics: Index; Source; Owner; Rx Drop Events; Rx Octects; Rx Pkts; Rx Broadcast Pkts; Rx Multicast Pkts; Rx Undersize Pkts; Rx Oversize Pkts; Rx Fragments; Rx CRCAlignErrors; Rx Pkts 64 Octets; Rx Pkts 65 to 127 Octets; Rx Pkts 128 to 255 Octets; Rx Pkts 256 to 511 Octets; Rx Pkts 512 to 1023 Octets; Rx Pkts ≥ 1024 Octets; Tx Octects; Tx Pkts; Tx Broadcast Pkts; Tx Multicast Pkts; Tx Discard Pkts; Ethernet Service Statistics: Index; Source; Owner; Priority; SVID; CVID; Rx Pkts; Tx Pkts; Rx Octects; Tx Octects; Rx Discard Pkts; Tx Discard Pkts; Rx Unicast Pkts; Tx Unicast Pkts; Rx Not Unicast Pkts; Tx Not Unicast Pkts; Ethernet Queue Statistics: Index; Source; Queue; Owner; Tx Pkts; Tx Octects; Tx Discard Pkts; Tx Discard Octets; Ethernet History: Time; Index; Source; Owner; Rx Drop Events; Rx Octects; Rx Pkts; Rx Broadcast Pkts; Rx Multicast Pkts; Rx Undersize Pkts; Rx Oversize Pkts; Rx Fragments; Rx CRCAlignErrors; Rx Utilization (%); Rx Min Utilization (%); Rx Max Utilization (%); Tx Octects; Tx Pkts; Tx Broadcast Pkts; Tx Multicast Pkts; Tx Utilization (%); Tx Discard Pkts; Tx Min Utilization (%); Tx Max Utilization (%); Ethernet Service History: Time; Index; Source; Owner; Priority; SVID; CVID; Rx Pkts; Tx Pkts; Rx Octects; Tx Octects; Rx Discard Pkts; Tx Discard Pkts; Rx Unicast Pkts; Tx Unicast Pkts; Rx Not Unicast Pkts; Tx Not Unicast Pkts; Ethernet Queue History: Time; Index; Source; Scheduler; Queue; Owner; Tx Pkts; Tx Octects; Tx Discard Pkts; Tx Discard Octets; NEW FW 1.1.0

SNTP – Simple Network Time Protocol Example14

Base Band – SNTP

... or using CLI

configure terminal sntp set sntp client version v4 set sntp client addressing-mode unicast set sntp unicast-server ipv4 192.168.80.1 primary version 3 set sntp unicast-server ipv4 192.168.79.1 secondary version 3 set sntp client enabled ; end ; logout

1 2

3

5

4 NEW FW 1.1.0

Features Management Main - Equipment Properties – Equipment Feature

enabling features keys

WLC is necessary for FTP file transfer specify laptop/NMS5 IP address

Unit List

Performance monitoring 2

programmed alarm relevant 15 minutes or 24 hours. Alarm Status

1 Counters recording: •ES = Errored Seconds •SES = Severely Errored Seconds •SEP = Severely Errored Periods •UAS = Unavailable Seconds •BBE = Background Block Errors •RLTS = Received Level Threshold Seconds (5 configurable threshold) •TLTS TLTS = Transmitted Level Threshold Seconds (4 configurable threshold) •RLTM = Received Level Tide Mark (Max, Min, Average Level) •TLTM = Transmitted Level Tide Mark (Max, Min, Average Level) •ACM = Adaptive Code Modulation (Mod Seconds,Unavailable, DownShift, UpShift)

Threshold

If the value = 0 sec, alarm is disabled

3

Report & Logger Maintenance 1

usefull during a troubleshooting

2

3

save all reports into the internal memory to preserve the events history

4

5 ... or using CLI show history

Details of alarms, commands and configuration stored in the radio. Up to (500 events)

CLI: show running-config SM-OS# show running-config interface ex 0/1 #Building configuration... ! interface extreme-ethernet 0/1 map switch default no shutdown bridge port-type customerNetworkPort port-based ! interface extreme-ethernet 0/1 shutdown flowcontrol send off flowcontrol receive off description "XGLAN" no shutdown switchport ingress-filter vlan max-traffic-class 8 switchport svlan-priotype copy no negotiation speed 10000 ! ! end SM-OS#

Show the actual running configurations of the XGLAN interface

NMS Wake Up Configuration Main Menu –NMS5 Wake Up Configuration

Manual Auto Discovery

Software info & Maintenance The new firmware is downloaded in standby bench (bench status: loaded). After a Bench switch, don’t turn off the power supply until a complete restart. Firmware Downgrade requires Restore + Bench switch

1 Open WebLCT Console 2 Download “only difference” FW_Boot.dwl 3 Download “Forced” FW_appl.dwl Preserve scripts loaded in Customer Configuration Default Factory procedure

2

specify laptop/NMS5 IP address WLC is necessary for FTP file transfer

1

3

4 Cold Restart

IP Factory Default Alfo+80HDX: 172.20.255.15/16 ODU H 172.20.254.14/16 ODU L

Backup/Restore Configuration c:\folder\filename.bak

specify laptop/NMS5 IP address Backup with WebLCT  Full Backup : EQUIPMENT-NAME_hhmmss-DDMMYY_v10100.bak not editable Backup with NMS5UX/LX  Full Backup : EQUIPMENT-NAME_hhmmss-DDMMYY_v10100.bak zipped not editable

Backup file made with NMS5UX/LX can be used to restore using WLC

!!! WLC is necessary for FTP file transfer !!! Backup/Restore file.bak must be done with the same system version

Alarm Severity Configuration 2

3 double click

1 It is used to avoid flickering of alarm: •Alarm is set when the event is persistent for more than 2.5 ± 0.5 s •Alarm is clear when the event is persistent for more than 10 ± 0.5 s

Disable or select the severity of the Alarm permanently 143

Site Rescue Config. 2

1

"Site Rescue" is used when the Field Engineer is not able to connect on the dedicated interfaces DCN for management (normal modality). In Site Rescue modality is not possible configure radio and Ethernet parameters, only the follow operation are possible : • Perform a Factory default setting [Main – Software Info & Maint. – Advanced] • Firmware update [Main - Software Info & Maint. – Equipment Firmware] • Change or check the unit IP Address subnetmask and default gateway only [Base Band – DCN – MNGT Port Configuration] • restore a backup file.bak [Main – Backup/Restore Config.] NEW FW 1.1.0

During power on of unit each LANs interface can be used for management connection using the Rescue IP address 172.20.253.13/16 and rescue profile user: rescue pass: rescue

User Manager

Read Only: Monitor user Read and write: cannot modified configurations of Equipment menu Maintenace: as Administrator user, but cannot create/modify user and add new Features Management

1 It’s required the creation of NMS5UX user for Server connection

2 Alarm trap Forwarding to a SNMP Server

3 3600

SIAEMICR SIAEMICR

5

4

6

Access Control List IP based (L3) Example 10

2 Deny All except 192.168.79.24

1

3 4

... or using CLI

configure terminal mgmt access-list 1 permit 192.168.76.24 255.255.255.255 priority 255 exit mgmt access-list 2 deny 0.0.0.0 0.0.0.0 priority 1 exit #access list L3 on the management vlan 1 interface vlan 1 mgmt access-group 1 in mgmt access-group access group 2 in end logout

from 1 (low) to 255 (high) priority level On MNGT VLAN interface

5

7

9

6

Host IP address

8

16=255.255.0.0 (the subnet 192.168.0.0) 24 =255.255.255.0 (the subnet 192.168.76.0) 32=255.255.255.255 (only one IP address) NEW FW 1.3.0

Security Configuration Equipment Menu – Main – Security Management

Radio Encryption Equipment Menu – Main – Security Management – Radio Encryption

1

1 - Create a new Group User with HTTPS, SFTP, SSH enabled [Main – Group/User Management – Groups] 2 - Create a new User that belong with new Group User [Main – Group/User Management – Users] 3 - Configure SSL with AES 128 and 256 [Main – Security Management – SSL/HTTP Secure] 4 - Generate Certificate [Main – Security Management – SSL/HTTP Secure] 5 - Signed Certificate [Using Win32OpenSSL.exe or SimpleAuthority.exe] 6 - Enter Signed Certificate [Main – Security Management – SSL/HTTP Secure] 7 - Enable HTTPS [Main – Security Management – Services Status Config] 8 - Inser the key and enable the Radio encryption [Main – Security Management – Radio Encryption]

148 NEW FW 1.5.0

RADIUS – Remote Authentication Dial–In User Service Equipment Menu – Main – Security Management – RADIUS

2

3 1 4

NEW FW 1.1.0

ANTITHEFT Equipment Menu – Main – Security Management – Antitheft

1

If the feature is enabled, in case of theft, the unit remain locked until it is repositioned in the initial state or is loaded an unlocked certificate.

NEW FW 1.2.0

Login Policy Equipment Menu – Main – Security Management – Login Policy

Temporary lockout timeout after n retries

The PSW must be changed after "expiration time" in days The user must change the default credential at the next login

User must not be logged simultaneously on different sessions

NEW FW 1.6.0

Sys Log client - RFC 3164 Equipment Menu – Main – Security Management – Login Policy

USER NE

1

Ext. Server File.log

2

SysLogger server port:514(udp) 3 4 Snmp settings

Login failed NEW FW 1.6.0

IP FORWARDING BaseBand – DCN – IP Forwarding

2 IP Forwarding is used to forward Management traffic in other interface available in the Network Element. In case of OSPF is mandatory keep IP Forwarding Enable.

1

NE interface VLAN1 interface VLAN4091

Loopback IP address

... or using CLI SM-OS(config)# ip forwarding {enable | disable}

NEW FW 1.6.0

Secured ARP BaseBand – DCN – Secure ARP Secure ARP is feature to avoid malicious attack like ARP Poisoning or also called ARP spoofing, that by means of falsified ARP messages over a LAN, the hacker is able to intercept data frames of victim

2

1

Host A (Client) IP = 192.168.0.10 MAC = aa:aa:aa:aa:aa:aa

Host C (Attacker) IP = 192.168.0.11 MAC = cc:cc:cc:cc:cc:cc ARP frame 192.168.0.1 is at cc:cc:cc:cc:cc:cc

INTERNET

Host B (Gateway) IP = 192.168.0.1 MAC = bb:bb:bb:bb:bb:bb

NEW FW 1.6.0

CLI: show logging SM-OS# sh logging System Log Information ---------------------Syslog logging : enabled(Number of messages 0) Console logging : enabled(Number of messages 4) TimeStamp option : enabled Severity logging : Critical Facility : Default (local0) Buffered size : 50 Entries LogBuffer(4 Entries, 4112 bytes) Apr 18 07:18:38 ISS FM [FM - MSR] : Configuration restored successfully. Apr 18 07:26:24 ISS CLI Attempt to login as admin via telnet from 10.30.1.249 Succeeded Apr 18 12:16:39 ISS CLI Attempt to login as admin via telnet from 192.168.0.2 Succeeded Apr 18 12:20:59 ISS CLI Attempt to login as admin via telnet from 192.168.0.2 Succeeded SM-OS#

MAB (Microwave Adaptative Bandwidth) protocol The Microwave Capacity Management protocol has been developed by SIAE and CISCO in order to improve the behaviour of the Ethernet ring protection when using the adaptive code modulation (ACM) on microwave links. The main ring topology advantages are: -To offer a protection path in case of equipment failure or radio link unavailability due to deep fading. -To increase Ethernet throughput (up to double) from the core toward the border of the network by distributing on the two ring branches the Ethernet traffic by means of control plane protocols (G.8032) in order to open the Ethernet loop in a suitable segment.

NEW FW 1.1.0

Signal to Noise Measure Modulation

ACM switching on S/N thresholds (Example of 1000MHz) Downshift

Upshift

256QAM

29.9

128QAM LP

27.6

31.5

128QAM

27.1

29.1

64QAM LP

24.6

29.1

64QAM

24.1

26.1

32QAM LP

21.7

26.1

32QAM

21.2

23.2

16QAM

18.3

23.2

16SQAM

15.5

20.3

4QAM LP

12.6

17.5

4QAM

12.1

14.1

4SQAM

9.9

14.1

4HQAM

9.9

14.9

4FQAM

9.9

14.9

Radio BER TEST to check Hardware Failure Local

1) Set Local Radio Timeout=0 2) Enable I/Q Loop or Baseband Loop in Local Radio

b

3) Enable Local Radio BER TEST(step a,b,c) 4) Check Local status: BER,Sync Loss, Errors, Elapsed Time, events

a

c

Timeout = 0 Ber Test on

RF Loop

Local ALFO+80HDX

Or for Both radio

This operation will result in the loss of remote equipment.

1) Set Timeout_Local= 580sec and Timeout_Remote= 600sec 2) Enable Remote Radio BER TEST(step a,b,c) 3) Immediately, enable the Local Radio BER TEST 4) Check Local status: BER,Sync Loss, Errors, Elapsed Time, events Timeout = 580 Ber Test on

Timeout = 600 Ber Test on

ALFO+80HDX Link

Local

LOOPS 0 sec = disable Manual operation Timeout Press Double click

(Traffic not squelched) = Ethernet packet is looped (the ingress packets ethernet from the LAN are re-send back to the LAN interface ; Very dangerous for the network, because the Ethernet traffic should never be looped). I/Q Loop

PHY1 PHY2 LAN3

LAN2

LAN4

XGLAN

MNGT

TRX

Loopback

Switch

BaseBand

Loops used with Ber Test measurement or S/N to search the failure or check the cable connections

Modulator

TX module

Demodulator

RX module

Manual Operation

Press click

PSU Alarm Config. In the menu WebLCT Maintenance - PSU Alarm Config

Disable/Enable Power Supply Unit alarms status on the connectors

NEW FW 1.6.0

Custom Configuration 3

2

1 4

5

NEW FW 1.1.0

IP Tools (L3) PING

SM-OS# ping 10.1.31.11 Reply Received From :10.1.31.11, TimeTaken : 10 msecs Reply Received From :10.1.31.11, TimeTaken : 30 sec)

-

Starting from Factory default, reconfigure manually the link.

-

Replace unit with a spare part.

Alarms grouping : Events list Alarms are divided into groups, the group name represents the origin of the module that has caused him.

Alarms group RADIO Group

Plug-in Group Base Band

PHY1 PHY2

LAN2

LAN3 LAN4

XGLAN

BER TEST

Modem

Switch

MNGT console

Mod

ETH Group

Demod

TX VCO RX

TRX CPU

COMMON Group Queue Depth Group OAM Group XPIC

SETS Group PTP Group P.M. Group Unit Group

Alarms Summary BaseBand (Alert) Protection (Alert)

Mod

TX

PHY2 LAN2

LAN3

ETH data LAN4 (Alert) MNGT console

XGLAN

BER TEST

Switch

Modem Demod

VCO

Microwave (Alert)

RX

TRX

Control Maintenance (Alert) CPU plane (Alert)

Power Synchonisation (Alert) (Alert) Performance XPIC Monitoring (Alert) Microwave HW (Fault) External (Fault) TX Mod

PHY2 LAN2

VCO

XGLAN Switch

MNGT console

Modem Demod

RX

TRX CPU

Configuration mismatch (Fault) External (Fault)

XPIC

Cable interface (Fault)

Air Interface (Fault)

Remote site

Base Band

PHY1

External LAN3 (Fault) LAN4

Remote site

Base Band

PHY1

Alarms groups : COMMON Alarms related to Controller module and EOC channel.

Alarm

Summary

Details

SNMP "Hello" request not acknowledged by NMS NE Manual Operation Maintenace Manual operations ongoing Conf. Site Rescue Site rescue procedure activated Mismatch NMS Wake Up

Control plane

Probable Cause "Management plane" communication problem External intervention of an operator Unexpected software event is recovered by "site procedure" to restore management access

Equipment manual operation Type 1 sec to clear all the active manual operation and press OK 2 3

1

Alarms groups: ETH LAN Alarms (internal and external) regarding Ethernet traffic and relevant ports.

Alarms groups: ETH LAN Alarm L->M Aggregation degrade

Summary Base Band, Air Interface

Base Band, Air L->M Aggregation down Interface Base Band, Air M->L Aggregation down Interface

LOS Port Protection configuration mimatch Physical port - LOS

ETH data Plane, External Protection, Conf. mismatch ETH data Plane, External

Physical port - LLF

ETH data Plane

Link Loss Forwarding

Base Band

Aggregation signaling down Queue Depth configuration mismatch

ETH data Plane, Conf. Mismatch Base Band, Conf. Mismatch

Details

Probable Cause

Ethernet L1 aggregated data path (from line Poor quality on one or more microwave links. Otherwise problem to microwave) degradation (at least one link on the local or remote radio interface or antennas outage) Ethernet L1 aggregated data path (from line Poor quality on one or more microwave links. Otherwise problem to microwave) degradation (at least one link on the local or remote radio interface or antennas outage) Ethernet L1 aggregated data path (from Poor quality on one or more microwave links. Otherwise problem microwave to line) outage due to lack of on the local or remote radio interface or antennas realignment External problem at the local Ethernet interface (media Ethernet signal missing on the related disconnected or configuration mismatch) or microwave link interface (LAN or Radio) outage Port protection logic is not activated; SW restart has been not Port protection logic not activated applied yet. Ethernet signal missing on the related External problem at the local Ethernet interface (media interface disconnected or configuration mismatch) Ethernet interface forced to "link down" by Microwave link outage or "link down" at the remote Ethernet interface link loss forwarding function Local Ethernet interface forced to "link Downlink radio link problem or Loss of signal at the remote down" by link loss forwarding function incoming Ethernet interface Traffic aggregation signaling channel out of Ethernet cabling incorrect or aggregated equipments misservice configuration HW queue length of the Ethernet switch is The selected queue profile it's not running; SW restart has been not congruent to the selected profile not applied yet.

Alarms groups: OAM Operation Administration and Maintenance Alarms : configuration and/or failure.

Alarms groups: OAM Alarm Y.1731 OAM - AIS

Summary

Control Plane Control Plane, 802.1ag OAM - Errored CCM Conf. Mismatch Control Plane, Y.1731 OAM - LCK Maintenace Y.1731 OAM - Loss of Control Plane, continuity Conf. Mismatch Control Plane, 802.1ag OAM - Mac status External Control Plane, Y.1731 OAM - Mismerge Conf. Mismatch Control Plane, 802.1ag OAM - RDI External Control Plane, Y.1731 OAM -RDI External 802.1ag OAM -Remote CCM Control Plane, defect Conf. Mismatch Y.1731 OAM - Unexpected Control Plane, MEG Conf. Mismatch Y.1731 OAM -Unexpected Control Plane, MEP Conf. Mismatch Y.1731 OAM -Unexpected Control Plane, period Conf. Mismatch Control Plane, 802.1ag OAM - CCM Xconnect Conf. Mismatch

Details

Probable Cause

AIS condition detected

OAM lower level in fault condition

MEP receiving invalid CCMs

Local vs. remote MEP mismatch

LCK condition detected

OAM lower level out of service due to forced maintenance

MEP not receiving CCMs from some other MEP Local vs. remote MEP mismatch (RMEP list or identifier) in its configured list MEP received CCM including a TLV port Status Anomalies at remote MEP Ethernet physical layer error about associated MAC MEP receiving CCMs that could be from some Local vs. remote MEP mismatch other MA/Level/Domain MEP receiving CCM including RDI bit activated Anomalies at remote MEP input MEP Receiving CCM including RDI bit activated Anomalies at remote MEP input MEP receiving CCMs that could be from some other MA/Level/Domain MEP receiving CCMs that could be from some other MA/Level/Domain

Remote MEP misconfiguration Local vs. remote MEP mismatch

MEP receiving invalid CCMs

Local vs. remote MEP mismatch (RMEP list or identifier)

MEP receiving invalid CCMs

Local vs. remote MEP mismatch (CCM period)

MEP receiving CCMs that could be from some other MA/Level/Domain

Local vs. remote MEP mismatch

Alarms groups: P.M. (Performance Monitoring) Alarms regarding Performance Monitoring section. Alarm

Summary

Details

P.M. ACM 15M

Perform. Monit.

P.M. ACM 24H

Perform. Monit. 24 hours performance counter threshold exceeded

Probable Cause

15 minutes performance counter threshold exceeded Radio link performance worse than expected Radio link performance worse than expected

P.M. G828 15M ES

Perform. Monit. 15 minutes performance counter threshold exceeded Radio link performance worse than expected

P.M. G828 15M SEP

Perform. Monit. 15 minutes performance counter threshold exceeded Radio link performance worse than expected

P.M. G828 15M SES

Perform. Monit. 15 minutes performance counter threshold exceeded Radio link performance worse than expected

P.M. G828 24H ES

Perform. Monit. 24 hours performance counter threshold exceeded

Radio link performance worse than expected

P.M. G828 24H SEP

Perform. Monit. 24 hours performance counter threshold exceeded

Radio link performance worse than expected

P.M. G828 24H SES

Perform. Monit. 24 hours performance counter threshold exceeded

Radio link performance worse than expected

Perform. Monit. Performance counter threshold exceeded

Radio link performance worse than expected

P.M. G828 UAS P.M. Rx Pwr 15M Rlst

Perform. Monit. 15 minutes performance counter threshold exceeded Radio link performance statistics acquisition

P.M. Rx Pwr 24H Rls

Perform. Monit. 24 hours performance counter threshold exceeded

P.M. Tx Pwr 15M Rlst

Perform. Monit. 15 minutes performance counter threshold exceeded Radio link performance statistics acquisition

P.M. Tx Pwr 24H Rlst

Perform. Monit. 24 hours performance counter threshold exceeded

Radio link performance statistics acquisition

Radio link performance statistics acquisition

Alarms groups: POWER Alarms regarding Power Supply input under voltage.

Alarm

Summary

PSU input under-voltage Power

Details Incoming power supply under-voltage

Probable Cause Cables, connectors or external battery damaged

Alarms groups: PTP Alarms regarding Precision Timing Protocol IEEE 1588.

Alarm

Summary

Details

Synchronisation, PTP servo is in "Free Running" status Conf. Mismatch PTP servo is in "Holdover in PTP Holdover In Specifications Synchronisation specification" status

PTP Free Running

PTP Holdover

Synchronisation

PTP servo is in "Holdover" status

PTP Port active

Synchronisation

PTP port is in "Active" status

PTP Port faulty

Synchronisation

PTP port is in "Faulty" status

PTP Port initializing PTP Port listening PTP Port uncalibrated

Synchronisation, PTP port is in "Initializing" status Config. Mismatch Synchronisation PTP port is in "Listening" status Synchronisation PTP port is in "Uncalibrated" status

Probable Cause No available PTP synchronization source due to configuration mismatch or PTP data link problem No available PTP synchronization source due PTP data link problems (or reconfiguration mismatch) No available PTP synchronization source due PTP data link problems (or reconfiguration mismatch) PTP synchronization source properly working PTP synchronization source out of service due to configuration mismatch or PTP data link problem State transition in progress on PTP synchronization source State transition in progress on PTP synchronization source State transition in progress on PTP synchronization source

Alarms groups: RADIO Specific alarms the ODU and Radio link.

Alarms groups: RADIO Alarm

Summary

Details

Probable Cause

BER Sync Loss

Maintenace

Poor quality of the received microwave signal, degraded by flat or SyncLoss detected by embedded BER meter selective fading or interference. Otherwise problem on the local or remote radio interface or antennas

TX Calibration in progress

Microwave

RF transmitter calibration

Internal calibration in progress

Base Band,Config. Local and remote link identifier aren't equal Local and remote link identifier mismatch Mismatch Received microwave signal, degraded by flat or selective fading or Base Band, Air Local/Remote telemetry channel loss of interference, or traffic configuration mismatch between local and Link Telemetry LOF Interface frame remote terminal. Otherwise problem on the local or remote radio interface or antennas Microwave , Air ACM modulation in use below the Microwave signal, degraded by flat or selective fading or interference. ACM reduced profile Interface maximum available Otherwise problem on the local or remote radio interface or antennas FMP - XPIC disable Microwave Local XPIC function is forced to off XPIC Fault Management Procedure intervention RF transmitter is shut down by remote FMP - TX Power off Microwave XPIC Fault Management Procedure intervention equipment request Microwave , Conf. RF transceiver parameters incongruent Parameter Mismatch Radio parameters misconfigurations Mismatch Received Microwave signal degraded by flat or selective fading or Base Band, Demodulator LOF Local demodulator out of lock interference. Otherwise problem on the local or remote radio interface External or antennas Link ID mismatch

Alarms groups: RADIO Alarm Frequency configuration mismatch

Summary

Details

Microwave, Configured frequency isn't compliant to Config. Mismatch equipment frequency raster

Probable Cause Frequency configuration error

RemoteDemodulator Base Band, LOF External

Remote demodulator out of lock

Remote received microwave signal degraded by flat or selective fading or interference. Otherwise problem on the local or remote radio interface or antennas

RF Frequency unlocked

RF transceiver PLL unlocked

RF transceiver faulty

Rx IF interface RX Power under threshold

Microwave, Microwave HW Microwave, Air Interface Microwave, Air Interface

Microwave RX Quality Microwave, Air low Interface Microwave RX Quality Microwave, Air warning Interface TX Power Fail XPIC cable LOS

Microwave, Microwave HW Microwave, External

RF receiver automatic gain control loop is ODU faulty or unexpected degraded received signal out of lock Received signal level under the configured Received microwave signal too low, degraded by flat or selective fading. threshold Otherwise problem on the local or remote radio interface or antennas Poor quality of the received microwave signal, degraded by flat or Signal to noise ratio below "Quality low selective fading or interference. Otherwise problem on the local or threshold" remote radio interface or antennas Poor quality of the received microwave signal, degraded by flat or Signal to noise ratio below "Quality warning selective fading or interference. Otherwise problem on the local or threshold" remote radio interface or antennas TX Power is out of range or RF transmitter is RF transmitter faulty or forced off by configuration switched off XPIC cable loss of signal

XPIC cable is missing, damaged or incorrect

Link ID Alarm is on if Link ID check is enabled (Link ID ≠ 0) and remote Link ID is different from the local one.

Traffic is cut but signal is received and measured. This alarm causes: - Traffic is cut - Management is cut

Link telemetry fail No link between Local and Remote station. Traffic & Mngt is cut.

BER synch Loss BER Test is an analyzer of RADIO Hardware failures. When you start the Measure, Sync Los Alarm appears and only after you active the RF Loop or Baseband Loop the alarm should disappears and BER value should decrease.

RT Rx Power Low This alarm occurs when Rx power is under a defined threshold Threshold value can be set in range: -40dBm  -99dBm in General preset The alarm Rx Power Low is a branch alarm and it is used to drive Rx switch

Decrease this value below of actual Prx, -70dBm is default value

RT Tx Power Low This alarm occurs when Tx power is 3 dB under the Tx Power control.

ATPC or manual attenuation do not affect this alarm that is given by internal failure of the radio. This alarm can be activated by a manual operation also: Tx Transmitter off in Radio Branch - Settings

RT Rx Quality Warning Alarm Good Quality of signal received = high S/N Signal to Noise = Signal / (noise + interferences) RX Quality Low Warning RX Quality Low Alarm BER ≈ 10E-6 BER ≈ 10E-10 Low BER threshold BER ≥ 10E-10

High BER threshold (Link is Down) BER ≥ 10E-6

Alarms groups: SETS Alarms relevant to the synchronism sources and their setting.

Alarm

Summary

Details

Probable Cause

Synchronism locked

Synchronisation Active synchronization source

Synchronism free running

Synchronisation SETS is in "free running" status

Not reliable external synchronization source

Synchronism holdover

Synchronisation SETS is in "holdover" status

Not reliable external synchronization source

Synchronism unlocked

Synchronisation

SETS is not locked to any external synchronization source

Not reliable external synchronization source

Synchronism source selected Synchronisation Active synchronization source Synchronism frequency drift

Synchronisation Synchronization source frequency out of range

Synchronism LTI

Synchronisation Synchronization source loss of signal

External synchronization source frequency out of specifications External synchronization source not available or degraded

Alarms grouping : SFP Alarms relevant the plug-in modules used for optical lines.

Alarm

Summary

Details

SFP unavailable

ETH Data Plane

SFP module unavailable

SFP High

ETH Data Plane

SFP module alarm high detected

SFP Warning (high)

ETH Data Plane

SFP module warning high detected

SFP Low

ETH Data Plane

SFP module alarm low detected

SFP Warning (low)

ETH Data Plane

SFP module warning low detected

Probable Cause SFP module absent or embedded memory corrupted External problem at Ethernet interface or module failure External problem at Ethernet interface or module degrade External problem at Ethernet interface or module failure External problem at Ethernet interface or module degrade

Alarms grouping : SUMMARY (Alert) Alarms related to the SUMMARY (Alert)

Alarms grouping : SUMMARY (Alert) Alarm Power Protection

Base Band

Microwave

Maintenance

Details

Control Plane Performance Monitoring

Resolution

Mains power under voltage due to cable, 1) Check power supply cable connectors or external battery; power over 2) Unit replacement Ethernet interface not properly working Protected data path outage Poor quality of radio or problem about 1) Check if the TDM cable is stuck in the connector or degradation protected data path Problems on cables and connectors, or 1) Check Microwave interface configuration "Data plane" outage or local/remote Radio parameters mismatch, or poor 2) Check the IF cable(*) operational degradation quality of the microwave link, or hardware fault 3) Restart the equipment (DS card included) 4) Replace SD Card (if available) or Unit 1) Check Microwave interface configuration Poor quality of the microwave link or local2) Check the IF cable(*) Degradation or outage of remote terminal configuration mismatch. 3) Check the remote TX power Associated to HW alarms, it indicates fault in the the microwave link 4) Replace Unit local demodulation chain, or microwave unit (*): if present or supported by the NE type

Power supply anomalies

Manual operation in progress

Ethernet data plane ETH Data Plane degradation or outage

Synchronization

Probable Cause

System synchronization doesn't work properly

Manual operations invoked by an operator

1) Maintenance operations have to be end

1) External problem on local Ethernet front end, SFP module absent or fault 2) 3) 1) External synchronization sources out of specification or absent

2) 3) 4) 1)

Check if the Ethernet cable/fiber is stuck in the connector Check Ethernet port configuration Check or replace SFP module Check if the tributaries cable/fiber is stuck in the connector Check/replace SFP module Check tributaries/Microwave configuration Check the Synchronization configuration Check if the ETH cable/fiber is stuck in the connector Check/replace SFP module Check L2/L3 protocol configuration

Anomalies on remote OAM peer, or "Control plane" outage or misconfiguration between local and remote peer, 2) operational degradation or "Control plane" communication problem 3) Performance monitoring Performance monitoring counters (15m or 24h) Clear alarm after proper analysis alarm thresholds exceeded exceeded their configurable threshold

Alarms grouping : SUMMARY (Fault) Alarms related to the SUMMARY (Fault)

Alarms grouping : SUMMARY (Fault) Alarm Configuration Mismatch

Details

Probable Cause

Ethernet data plane Presence of equipment Incongruent configuration degradation or outage due parameters to mis-configuration

Resolution 1) Make local and remote configuration matching

1) End the maintenance operation 2) Replace the unit 1) Replace the Cable (*) Internal communication Cable Interface Internal communication problem 2) Replace Microwave unit problem (*): if present or supported by the NE type 1) Check Microwave interface configuration 2) Check matching of local/remote equipment Poor quality of the received microwave signal, configurations (e.g ACM-TDM) Microwave link degraded degraded by flat or selective fading or interference. Air Interface 3) check quality of the microwave link Otherwise problem on the local or remote radio performance or outage 4) check the remote TX power interface or antennas 5) check the demodulation chain by Radio loops (if present) 1) Search the cause out of the NE (e.g: cable is stuck Alarm external to the system in the connector, network configuration or out of External External cause on the relevant interface located on its interfaces service on other link, receive problem on the remote ..) Microwave HW Generic HW failure

HW faulty or invasive manual operation in progress

Alarms grouping : UNIT This group generates alarms when one of the units, the equipment consists of, is faulty or does not respond to controller polling

Alarm

Summary

Details

Unit Fail

Microwave HW

HW mismatch

Config. Mismatch Expected vs. actual unit mismatch

Actual unit isn't congruent to the provisioned one, replacement or re-configuration needed

Unit Missing

Base Band

Expected unit missing

Unit hardware not detected by the main controller

Not Responding

Cable Interface

Embeddeded communication failure

Unit isn't able to communicate to the main controller

Unit software unexpected

Actual unit software isn't supported by the main controller

SW mismatch

Config. Mismatch

Generic unit hardware failure

Probable Cause Unit hardware damaged, replacement needed

ACRONYMS

More info? …consult the manual ALFOplus80HDX - User manual (mn.00387.e).pdf WEB LCT ALFOplus80HDX - User manual (mn00382.e).pdf Ethernet switch configuration - User manual (mn.00320.e).pdf

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