NEC IPASOLINK 400 INSTALLATION AND PROVISIONING © Pekka Linna NEC Finland Oy 2012 2 CONTENTS INTRODUCTION ......................................................................................................................6 PRODUCT DESCRIPTION .....................................................................................................6 IPASOLINK 400 ........................................................................................................................7 COMPATIBLE OUTDOOR UNITS ........................................................................................8 NHG .....................................................................................................................................8 NHG2 .....................................................................................................................................8 IHG .....................................................................................................................................9 BLOCK DIAGRAMS ................................................................................................................9 AVAILABLE CONFIGURATIONS .......................................................................................11 UNPROTECTED HOP .......................................................................................................11 PROTECTED CONFIGURATIONS .................................................................................11 ETHERNET PROTECTION USING 2+0 OR XPIC 1+0 ..............................................................11 RADIO TRAFFIC AGGREGATION .............................................................................................11 CONFIGURATION DIAGRAMS .................................................................................................12 ASYMMETRICAL HOPS ...........................................................................................................15 EXTERNAL CONNECTION SPEED AND RADIO PATH CAPACITY ..........................15 IPASOLINK CAPACITY.............................................................................................................16 QOS AND OVERPROVISIONING .......................................................................................18 ADAPTIVE MODULATION ...................................................................................................18 MAIN SPECIFICATIONS ......................................................................................................20 IDU CONFIGURATIONS .......................................................................................................22 PDH-INTERFACES ............................................................................................................24 MANAGEMENT AND AUXILIARY INTERFACES ........................................................................24 3 INDOOR UNIT CONFIGURATIONS ...................................................................................25 ORDERING CODES ..............................................................................................................26 PREINSTALLED LICENSES ...............................................................................................26 SAFETY ISSUES....................................................................................................................26 OPEN WAVEGUIDE AND OPTICAL CONNECTORS ..................................................................26 AVOID THE FRONT OF THE ANTENNA ....................................................................................26 RADIATION MONITORING DEVICES ............................................................................27 SAFETY DISTANCE FOR THE PUBLIC EXPOSURE ..................................................27 INDOOR UNIT INSTALLATION ..........................................................................................28 VENTILATION .....................................................................................................................28 ENVIRONMENTAL REQUIREMENTS ........................................................................................28 POWER CONNECTION ............................................................................................................29 ASSEMBLING THE POWER CABLE ..............................................................................29 ETHERNET CABLE CONNECTIONS .............................................................................30 PDH CONNECTIONS ...............................................................................................................30 ODU INSTALLATION ............................................................................................................30 6 GHZ ODU WITH STANDARD WAVEGUIDE ...............................................................31 SEPARATE INSTALLATION OF 7 AND 13 GHZ DIRECT MOUNT ODU......................................32 DIRECT MOUNT INSTALLATION ...................................................................................32 ODU CABLE INSTALLATION ....................................................................................................34 CABLE CONNECTORS .....................................................................................................35 GROUNDING ......................................................................................................................35 Grounding outside .................................................................................................................................... 35 Grounding in the shelter .......................................................................................................................... 36 Suitable grounding connectors ............................................................................................................... 36 4 IDU AND CABLE LABELLING ...................................................................................................36 OVERVOLTAGE PROTECTION ................................................................................................36 LOCAL MANAGEMENT .......................................................................................................37 MANAGEMENT TOOL .......................................................................................................37 RECOMMENDED BROWSER ...................................................................................................37 LOCAL CONNECTION .............................................................................................................37 REMOTE LOGIN USING THE BROWSER..................................................................................38 LOGIN WINDOW ................................................................................................................38 MAIN PAGE – MENU AND CURRENT STATUS .........................................................................39 NAMING OF THE IDU AND MODEMS .......................................................................................39 BASIC SETTINGS..................................................................................................................39 PROVISIONING CLEAR....................................................................................................40 NETWORK MANAGEMENT (NMS) SETTINGS ............................................................47 MODEM SETTINGS ...........................................................................................................51 SYNCHRONIZATION SETTING ...............................................................................................52 DATE AND TIME SETTING .......................................................................................................55 NETWORK MANAGEMENT SECURITY SETTINGS ...................................................................56 ANTENNA ALIGNMENT .......................................................................................................61 MANAGEMENT NETWORK ................................................................................................63 DCN OVER PDH/SDH ..............................................................................................................65 MANAGEMENT USING METRO ETHERNET VPLS SERVICE ..................................65 PROVISIONING PDH ............................................................................................................66 ETHERNET SETTINGS ........................................................................................................69 VLAN SETTINGS .....................................................................................................................70 BRIDGE MODES (802.1Q AND 802.1AD) ..............................................................................72 5 SAMPLE VLAN SETTINGS .......................................................................................................73 QOS SETTINGS .....................................................................................................................76 TRAFFIC CLASSIFICATION PRINCIPLES ....................................................................76 SAMPLE QOS POLICY......................................................................................................79 QOS SETTINGS – CLASSIFY AND INGRESS POLICING ..........................................80 PORT QOS SETTINGS .............................................................................................................82 QOS SETTINGS SUMMARY .....................................................................................................84 COPYING SETTINGS FROM ONE IDU TO ANOTHER..................................................85 PRECONFIGURATION FILES .............................................................................................90 KNOWN PROBLEMS ............................................................................................................91 APPENDIX A. RECEIVER THRESHOLD DATA ..............................................................92 APPENDIX B. MC-A4/16E1-A MDR68-CONNECTOR PIN LAYOUT ..........................95 APPENDIX C. MC-A4 D-SUB-44 CONNECTOR PIN LAYOUT ...................................96 APPENDIX D. QUICK INSTALLATION GUIDE/CHECK LIST ......................................97 Version 2.4 2012-09-20 6 INTRODUCTION This document describes the installation and provisioning of NEC iPasolink 400 microwave transmission equipment. The information is based on the IDU firmware version 3.00.37. Additional information is available in the manual iPasolink 400 Installation, Operation and Maintenance (NWD-115474-05E). iPasolink 200 and iPasolink 1000 are very similar; however, there are some differences due to hardware configurations. Reference is made to the appropriate equipment manuals. Appendix D contains a quick provisioning guide. The quick guide is based on the configuration files that have to be copied to the equipment before using the quick setup. The configuration files have to be customised for each customer’s basic HW configuration. Rebooting of the equipment with traffic interruption will take place when the configuration file is copied to the equipment. PRODUCT DESCRIPTION The microwave transmission family (iPasolink 100/200, 400 and 1000) enables full duplex wireless transmission between two modems at a rate of over 400 Mbit/s per direction. With XPIC and radio channel aggregation, over 800 Mbit/s per radio channel can be achived. The interfaces are based on the Ethernet, PDH and SDH standards. Frequency division duplex is used. A pair of channels separated by certain duplex spacing is required. iPasolink uses licensed frequency bands. The frequency administration provides interference-free channels to different operators based on frequency planning: transmitter powers and antenna sizes etc are specified. Alternatively, in some countries, the operator may be given a block allocation of spectrum and the operator is then responsible for the proper frequency planning inside the block. In any case, the correct operation is only possible with proper frequency planning so that adequate signal-to-interference margin is available. Moreover, the microwave hop has to be planned according to current ITU-R methods in order to ensure sufficient margin against fading. NEC iPasolink uses the traditional split mount installation method: indoor unit (IDU), coaxial cable, outdoor unit (ODU) and antenna. Different products of the iPasolink 100/200/400/1000 family may interface over the air with certain limitations regarding maximum modulation. Fully outdoor versions (iPasolink AX, SX and EX) are also available but are not over-the-air compatible with iPasolink 100, 200, 400 or 1000. The indoor unit contains the baseband interfaces (nxE1, STM-1, FE or GbE) as well as modems, a power supply (or supplies) and a control unit with NMS interfaces. The interconnecting cable uses intermediate frequencies below 400 MHz for the data and control signals. It feeds the power to the outdoor unit at -48 7 V. The frequency bands available cover the standard bands 6 to 42 GHz. Microwave signals do not penetrate buildings, vegetation or terrain nor bend around obstacles. Therefore the antenna has to be placed on top of a tall building or on a tall tower or mast in order to provide free line-of-sight connection to the opposite end. IPASOLINK 400 This guide is based on the middle-sized member of the family, the iPasolink 400. It may contain up to four (4) modems. Each modem can provide Ethernet L2 capacity 10 to 400 Mbit/s or PDH/SDH capacity up to 152 x E1 or 2 x STM-1 or various combinations. The actual capacity depends on the available channel width and available signal to noise/interference ratio and the fade margin required to fulfil the availability targets. In the most basic configuration only one of the four slots contains a modem. The main card has always FE/GbE and E1 interfaces. The other slots may contain additional GbE, SDH or E1 interfaces or modems. In addition, TDM over packet (PWE), Synchronous Ethernet etc. options are available. The highest capacities (400 Mbit/s) require access to a frequency band with 55 to 60 MHz channel spacing, typically such channels are available in the upper 6 GHz, 18 GHz, 32 GHz or 38 GHz bands. On such bands where the maximum spacing is only 27.5 or 28 MHz, the maximum capacity per modem is limited to about 200 Mbit/s. If necessary, two modems can share the same channel by using orthogonal polarizations and XPIC (cross-polarization interference canceller). In such a setup the maximum combined capacity is about 400 Mbit/s (27.5 or 28 MHz channels) or about 800 Mbit/s (55 or 56 MHz channels). The element management connection is based on Ethernet/IP transmission. All elements should be connected to an EMS (PNMSj or MS5000). Within each iPasolink cluster the management traffic is carried internally and separated from the customer traffic. A dedicated gateway connection (NMS port) to the management data communication network (DCN) is typically used at the “root” element of the cluster. Another solution is to use a traffic interface at the root element (in-band connection to root element). Figure 1. iPasolink 400 indoor unit (IDU). 8 In the unit in Fig. 1 two modems (left) and a GbE interface card (right) have been installed. The unused slot is covered by a blank cover. In the lower part are (from the left): the main card, a power supply, an unused power supply slot and the fan unit. COMPATIBLE OUTDOOR UNITS Figure 2. Compatible outdoor units. Indoor units: IHG is the latest version, silver coloured. NHG2 is white on the higher bands and beige on the lowers bands whereas the NHG and the 6 to 11 GHz NGH2 look identical. Any two IDUs belonging to the iPasolink 100/200/400/1000 family can be connected over the air. Note that iPasolink IDU cannot interface to a previous generation (e.g. PASOLINK NEO) IDU. However, older generation ODUs can be reused with iPasolink IDUs. There are certain limitations presented below. NHG NHG does not support 256QAM or higher modulations; only 128QAM and lower modulations formats are guaranteed to work properly. When used with iPasolink IDU the FW version of the NHG ODU has to be 3.50 or later. This upgraded ODU will not work with a Pasolink NEO IDU any more - unless FW is downgraded back to 3.50. NHG2 NHG2 FW 4.06 works only with an iPasolink IDU. Earlier FW versions than 4.06 work only with Pasolink NEO IDU. The recommended NHG2 FW version is 5.08 or later, which are compatible with both Pasolink NEO 9 and iPasolink indoor units. NHG2 upgrade to level 5.08 from lower level than 4.90.0 is a two-step upgrade: to level 4.90.0 first and then to level 5.08 or later. IHG IHG FW version should be 5.08 or later. IHG will then work with iPasolink and PASOLINK NEO. BLOCK DIAGRAMS The block diagram of iPasolink 400 Indoor Unit (IDU) is presented in Figure 3. The Outdoor Unit (ODU) is described in Figure 4. The IDU main card has a separate TDM switch and a packet network L2 switch. It supports natively both circuit-switched TDM as well as packet-switched Ethernet transport modes. In addition the equipment supports the ”TDM-over-Ethernet” mode when equipped with the PWE option. The modulator part of the modem generates an intermediate frequency signal. It is modulated by the digital baseband signals and sent up to the ODU. The demodulator part demodulates the intermediate frequency signal coming down from the ODU. The demodulator includes an adaptive equalizer which repairs the linear distortions (poor amplitude and phase response of the channel) caused by multipath fading. It also includes a FEC (Forward Error Correction code) which is able to correct bit errors even very close to the threshold receive level. The system is almost error-free until very close to the threshold and the transition to outage is within a couple of dB. It is possible to equip the iPasolink 400 and 1000 IDUs with two redundant power supplies. Interruption of one -48V supply voltage or a fault in one power supply unit will not cause any traffic interruption. Note: iPasolink 100/200 has two independent connections to external -48V voltage but does not contain a redundant power supply unit. 10 Figure 3. iPasolink 400 IDU, block diagram. Figure 4. IHG ODU, block diagram. The Outdoor Unit (ODU) generates the final microwave signal using the IF signal from the IDU by upconverting it one or two times (MIX). The output of the mixer is band-pass filtered (BPF) in order to remove the unwanted mixing products and then power amplified (PA). In the receive direction there is a Low Noise Amplifier (LNA) and a mixer/filter which generates the receive direction IF signal. The local oscillator (LO) frequencies are synthesized and controlled by the Control unit (CTRL). Transmitter output power is fine-controlled automatically according to the modulation used and optionally based on the remote end received power (Automatic Transmit Power Control, ATPC). Both the modem in the IDU and the ODU contain a duplexer (DUP, MPX) which combines the different directions of transmission to the same cable connector. The ODU power supply uses the DC voltage (-48V) 11 connected to the single coaxial cable centre conductor. The ODU can be mounted up to 500 metres from the IDU, when a high-quality (e.g. ½ inch low-loss) coaxial cable is used. AVAILABLE CONFIGURATIONS UNPROTECTED HOP The most basic configuration is a 1+0 or unprotected hop between a pair of modems. A single iPasolink 400 IDU can have up to four (4) 1+0 connections to separate sites. In this maximum configuration four ODUs, four antennas and four coaxial cables are needed together with one IDU and four modems. PROTECTED CONFIGURATIONS If the requirement for the service restoration time after a failure is very strict, there is no time to go to the site to replace the failed unit. In some cases the Service Level Agreement (SLA) does not allow any service interruption caused by equipment failures. In such cases a 1+1 protected hop can be used. Both transmitters may be transmitting always, each using a separate channel (frequency diversity, twin path). Alternatively the spare transmitter is activated and the main transmitter muted only during a transmitter failure (hot standby). In both solutions the receivers and demodulators are always activated and the IDU will select the better (less bit errors) signal for processing. The reliability (MTBF) of iPasolink is very high, which means that the traffic MTBF of the 1+1-solution is extremely high, provided that the first fault is repaired within a reasonable time (within a few days). The main disadvantage - in addition to double equipment cost - of the 1+1-solution is that the number of equipment faults will double compared to the 1+0 solution. As an expample: if the equipment MTBF of a 1+0 hop is 100 years, then the MTBF of a 1+1 hop is approximately 50 years. But the traffic MTBF of a 1+1 hop could be perhaps 1000 years, however, depending on the fault repair time. Another disadvantage of the 1+1 twin path solution is that only 50% of available capacity per MHz is in actual use. ETHERNET PROTECTION USING 2+0 OR XPIC 1+0 A more cost efficient solution to protect Ethernet connections is to use 2+0 (or XPIC 1+0) on the same hop. The traffic is then distributed between two modems and ODUs. The normal capacity could be as high as 800 Mbit/s. In case of a failure of an ODU, as an example, the traffic may still use the other ODU at 400 Mbit/s. It is possible to use a dual-polarised antenna with XPIC (Fig. 7). It should be noted that the partial equipment protection using “1+0 XPIC” is not fully automatic: the non-functional side transmitter has to be muted manually in order to operate the remaining side at full speed. RADIO TRAFFIC AGGREGATION Radio traffic aggregation (RTA) to a single external Ethernet external interface can be done at L2 or L1 level. 12 When using L2 aggregation, a single “stream” is not distributed to the two radio paths due to the known limitation of the standard LAG method. Several streams (e.g. different MAC DA or SA) are needed in order to use the full capacity. The more advanced NEC proprietary L1 aggregation (Physical RTA, PRTA) method will create a genuine combined Ethernet port towards the air and even a single Ethernet stream can use the full capacity. Modem versions supporting L1 aggregation PRTA: see Table 6 below (page 24). CONFIGURATION DIAGRAMS Figures 5 to 7 present the available configurations for iPasolink. Figure 5. Basic configurations From top to bottom, Figure 5 shows first a basic 1+0 hop, then a 1+1 Hot Standby (HS) and finally a threeantenna Space Diversity (SD) solution combined with HS protection. A single antenna is used with a hybrid (HYB). The hybrid will cause some extra attenuation in the radio path, with a corresponding loss in the fade margin and increase in the outage time caused by fading. The three-antenna SD solution is thus less effective than a genuine SD solution. In addition the space diversity in the right-to-left direction is based on transmitter switching, which is not hitless (bit errors when switching over). 13 Figure 6. Additional configurations. Figure 6 shows on the top a HS/SD solution using four antennas per hop. This is the best solution for long hops: no loss of fade margin and switching is hitless in both directions. The middle solution is 2+0, i.e. two working channels and no protection channel. However, considering Ethernet traffic, 2+0 has some protection against a single equipment failure. Two separate radio channels are required and when properly configured, when a fault occurs in an ODU or modem, L2 or L1 aggregated packet traffic is automatically rerouted to the remaining working channel. Half of the packet capacity is still available when one channel is faulty. The bottom configuration in Fig. 6 is an aggregation node solution: separate sites connected to a single IDU and a single Ethernet connector. One or more radio channels will be needed depending on the angular spacing of antenna directions. In principle 4+0 without XPIC can be even used on a single hop but then four radio channels are needed. It is possible to use less radio channels on the same hop using XPIC and crossed polarizations (Figure 7 below). The modems are interconnected using XPIC cables. The system calculates the original signals using all available information, i.e. both IF signals are connected to both modems. 14 Figure 7. XPIC configurations. Figure 7, top, shows a basic XPIC 1+0 (could be called XPIC 2+0 as well). It uses a single channel pair, two polarizations and four modems per hop over a single antenna per site. Double capacity is achieved without using any extra spectrum. Note: 1+0 XPIC partial protection for aggregated packet traffic is not automatic. When a fault occurs preventing the use of XPIC, the interfering transmitter has to be manually muted (either locally or remotely) in order to remove the interference and allow maximum speed operation of the remaining modem. 15 This solution uses a dual-polarized antenna with an integrated Orthomode Transducer (OMT). Four ODUs can be attached directly to a single antenna without any cables or waveguides between the antenna and the ODU. The middle part of Figure 7 shows a 1+1 XPIC solution: it is protected against modem, cable and ODU faults. A single fault will not affect the traffic capacity. This solution uses a hybrid connection between antenna and the ODUs to connect two ODUs at a different frequency to the same antenna port. The last solution with separate IDUs is the most complex but also best protected against equipment failures. An external Ethernet switch is required at each end for traffic rerouting. Switching or load balancing can be based on Link Loss Forwarding (LLF) or Link Aggregation Group (LAG). This solution protects against practically all IDU failures. XPIC requires the use of dual-polarized antennas. If an XPIC upgrade is anticipated, a dual-polarized antenna with an integral OMT for two or four ODUs may be installed initially. The unused ports are protected by blanking plates and gaskets and the empty fixing screw holes should be fitted with a screw, washer and rubber washer in order to keep the OMT interface clean and ready for ODU and cable installation later. ASYMMETRICAL HOPS Often the two ends of the hop are identical. But it is possible to use a different IDU (e.g. iPasolink 400 or 1000 in the aggregation node and iPasolink 200 or 100 in the remote end). The interface type can be different (e.g. FE in the remote IDUs, optical GE in the aggregation IDU). Several Ethernet ports may be used in one end and aggregated to a single port in the other end. Similarly, it is possible to aggregate n x E1 interfaces of a long chain of links to a single STM-1 interface at the trunk network node. In other words, the E1 channels of a modem can be cross-connected to the 16 x E1 connector of the main card, to another modem or to a time slot in the STM-1 connection. EXTERNAL CONNECTION SPEED AND RADIO PATH CAPACITY The total L1 capacity of the external Ethernet interfaces of an IDU may well exceed the available radio path capacity. This is normal, of course. The type and speed of the external interface is selected based on the external requirements. It is the sum of the L2 traffic carried by the interfaces at a given moment (plus the available buffering capacity in iPasolink) that must fit in the radio channel. Note that iPasolink only transmits the L2 bytes over the air. Constant L1 overhead bytes are removed and restored by the system (L1 compression). For this reason the corresponding external L1 speed is always greater than the L2 capacity needed to transmit the information at the air interface (Figure 8). 16 Figure 8. Typical Ethernet frame. Preamble, Start of frame delimiter and Interframe gap (L1 overhead) are never transmitted over the air. Optionally also MAC destination and Mac source adresses may be compressed. The highlighted octets (20 octets) in Figure 8 are removed and instead three octets are added for internal purposes. The net compression is 17 octets per frame. The effect of compression is only significant when frames are very short (in the order of 64 to 512 octets). There is no compression gain at all when the average frame size is large (e.g. 1500 octets/frame). Optionally L2 layer compression of MAC addresses can be used. This will remove almost 12 octets, assuming that only a very few MAC addresses are in use at a given time. In the same way as for L1 compression, removing some octets has no significance when the average frame size is large. When talking about link capacity, it is always recommended to define if it is measured at the external interface at L1 level (including and counting all octets) or if it is the L2 capacity. The difference is only significant when small frames are used for the measurement. IPASOLINK CAPACITY Table 1 shows examples of maximum capacities available in iPasolink currently. Modulation Channel Spacing (MHz) Frame size (L2 octets) Radio capacity L2 + internal (Mbit/s) 256QAM 256QAM 256QAM 512QAM 512QAM 512QAM 64 1500 8000 64 1500 8000 367 367 367 412 412 412 56 56 56 56 56 56 External L1 capacity occupied (Mbit/s) 460 371 367 517 417 413 L2 capacity transmitted (Mbit/s) 350 366 367 394 412 412 Table 1. Example capacities at various frame sizes (L2 MAC compression not used) The above figures show how the L1 capacity required at the external interface is much larger than the radio capacity used for small frames. On the other hand, the available L2 radio capacity is best used with large frames (internal use of three octets per frame becomes negligible). For a reference, Table 2 shows the standard 1000 Mbit/s GbE L2 speeds for the same frame sizes as above. As always, the available L2 speed depends on the frame size and the L1/L2 difference vanishes with large frames. 17 Frame size (L2 octets) 64 1500 8000 L1 capacity (Mbit/s) 1000 1000 1000 L2 capacity (Mbit/s) 761,9 986,8 997,5 Table 2. GbE interface L2 capacity also depends on the frame size. If the average frame size were only 64 octets, there would be a problem fitting the 2+0 maximum capacity at 56 MHz and 512QAM into a single GbE interface. This is because the total L2 speed is 2 x 394 = 788M, which would need over 1 Gbit/s at interface L1 speed (2 x 517 = 1034M). In other words two modems could send more packets than a single GbE interface can handle. In practise the average packet size is always much larger than 64 octets, perhaps 500-1000 octets, and then the GbE interface can handle all the packets delivered by two modems. The compression can become an interpretation problem when measuring the link capacity with the smallest frame size. If the capacity is defined using the smallest frames only, that capacity cannot be achieved with real traffic and a larger average frame size. This may cause SLA problems between the operator and the end customer. It is recommended that the capacity is defined and measured using the largest possible frames which will remove the L1/L2 difference. Then the real capacity achievable is always slightly larger than the measured one. Table 3 shows iPasolink radio capacities with each available modulation and channel spacing. This value is practically identical with the L1 and L2 capacity when the average frame size is 1500 octets or larger. (1024QAM and 2048QAM are preliminary values). Modulation QPSK 16QAM 32QAM 64QAM 128QAM 256QAM 512QAM (1024QAM) (2048QAM) Radio capacity (Mbit/s) Channel spacing 7MHz 14MHz 28MHz 10 22 45 22 45 91 27 56 113 33 67 136 39 79 159 45 90 182 205 (228) (251) Table 3. iPasolink radio capacity. 56MHz 91 183 228 274 320 366 412 (458) (504) 18 QOS AND OVERPROVISIONING If the traffic coming to the IDU is very bursty and time-variable, so called “overprovisioning” (or “overbooking”) of the radio is a possible method for cost savings. Due to the statistical variation and the fact that the traffic peaks seldom occur simultaneously. The combined traffic has a peak value less than the sum of the peak values of contributing interfaces. The random nature of real traffic will sometimes cause the radio channel to be overloaded. This will happen more often when unfavourable weather conditions force the use of lower modulation formats (when adaptive modulation, AMR, is used). Overprovisioning must take into account overloading conditions and the priority of frames must be considered. Obviously less important traffic and non-realtime traffic should be dropped first. iPasolink can use statistical multiplexing very effectively because it understands the incoming frame priority, it may shape the traffic and there is a queuing mechanism to the radio path. The operator should design the radio capacity based on the traffic statistics and SLA requirements and define the QoS parameters required in the radio. ADAPTIVE MODULATION As was the case already with the previous generation PASOLINK NEO HP AMR, iPasolink may use adaptive modulation (AMR) which improves the reliability of high priority traffic or alternatively increases the available capacity for lower priority traffic during majority of time. AMR is especially important when using high modulation formats with lower sensitivity and lower fade margin resulting in higher equipment costs such as larger antenna. With AMR different traffic classes may have a different fade margin and availability. Figure 9. Adaptive modulation. An example: the most cost-efficient solution could be that a nominally 366 Mbit/s hop is designed for 99,9993% availability for 16QAM 183 Mbit/s for “Business Critical and Real Time” traffic. For Best Effort traffic, the full 366 Mbit/s 256QAM availability could be 99,993% of time. In this manner, the last 25% of traffic (e.g. Real Time) would have practically 100% availability (91 Mbit/s QPSK). This kind of availability 19 design is of course based on the empirical rain and multipath fading models for the average worst month. No real guarantee for the availability due to weather conditions can be given, but statistically the designed hops will meet the targets. A more expensive solution would be to design the hop for 99,999% availability for the full 256QAM 366 Mbit/s. This would mean using larger antennas and/or shorter hop lengths (i.e. additional CAPEX). The adaptive modulation would then ensure that high priority traffic at lower capacity would have much better availability. It is crucial that the hop attenuation after aligning the antenna is correct when compared to the fade margin calculation. If the designed fade margin is not available, the availability for the various traffic classes cannot be achieved. 20 MAIN SPECIFICATIONS The following tables present the main technical specifications of the iPasolink 400 equipment. Some performance data are given in Appendix A. ODU frequency bands Capacity per modem (*512QAM Modem HW 2.00 and later) External line signals and interfaces IDU-ODU connectors, cable attenuation allowed ODU RX level monitor connector Channel QPSK spacing and 16QAM radio capacity 32QAM 128QAM 256QAM 512QAM Environmental conditions (ODU for outdoor use, IDU for temperature-controlled indoor use or outdoor cabinet with similar conditions) Power supply Power consumption (1+0) Mechanical data LCT (local element management) Management port Service Channels (SC) External relay output/input (AUX/ALM) Others PDH SDH LAN 6, 7, 8, 10, 11, 13, 15, 18, 23, 26, 28, 32, 38, 42 GHz 1x155 Mbit/s tai < 412 Mbit/s* 152 x E1 (256QAM) 2x155 Mbit/s E1 (ITU-T G.703) S-1.1/L-1.1 (ITU-T 10/100/1000 Base75/120 ohms G.957): LC T(X):RJ-45 MDR-68 female (16xE1) ITU-T G.703: DIN 1000 Base-SX/LX: LC (See Appendix B and C). 1.0/2.3 ODU: N-female 50 ohms IDU: TNC-female 50 ohms Maximum attenuation: 25 dB at 340 MHz (E.g. Draka RFA ½” > 500m) F-female (DC voltage proportional to the input level at antenna port) 7/14/28/56 MHz 11/22/45/91 Mbit/s 7/14/28/56 MHz 22/45/91/183 Mbit/s 7/14/28/56 MHz 28/56/114/229 Mbit/s 7/14/28/56 MHz 39/79/160/320 Mbit/s 7/14/28/56 MHz 45/90/183/366 Mbit/s -/-/28/56 MHz -/-/205/412 Mbit/s Full specifications: ODU: -33…+50 ˚C, IDU: -5…+50 ˚C Operation guaranteed: ODU: -40…+55 ˚C, IDU: -10…+55 ˚C Transportation: ODU, IDU: -40…+70 ˚C Relative humidity: ODU: 100 % IDU: 90 % (no condensing allowed) -48 VDC (-40,5… -57 VDC), Fuse/over current protection > 10A (6A for max 3 x ODU) ODU: 30 W (6-11 GHz), 23 W (13-52 GHz) IDU: 45 W + 10W/modem + 8W/GbE-card Total < 210 W (fully equipped, feeding four 6 GHz ODUs) ODU: 237(l)x237(w)x101(h); ~3-3,5 kg IDU: 19” 1U (483x44x240mm); ~3-4 kg (including plug-in units) LCT port: RJ45 10/100Base-T using a web browser NMS/NE ports: RJ-45 10/100 Base-T RS-232C 9600 bit/s 2 ch., V.11 64/192 kbit/s 2ch; D-44 female (See App. F) D-44 female (See Appendix F) USB-port for a memory stick (USB v.2.0) Table 4. NEC iPasolink 400 main technical data 21 Switching capacity MAC-table VLAN Jumbo frames QoS ETH OAM Equipment/traffic protection Traffic aggregation over the air Synchronous Ethernet TDM PWE Other 48 Gbit/s (theoretical, exceeds the maximum interface capacity available per IDU) Address table per each VLAN 128k (configurable) 802.1Q port and tag, tunnel 802.1ad port and tag, selective 4094 VLAN ID per IDU MEF9 certified EPL, EVPL and ELAN; L2CP tunnelling (multicast frame filtering/forwarding configurable) max. 2000/9600 octets (FE/GE) Ingress ports Configurable mapping QoS -> internal priority: based on VLAN CoS/IPv4 DSCP/IPv6 DSCP/MPLS Exp Configurable mapping internal priority -> 4/8 egress queues (port based setting: default one to one and two user profiles plus one user-defined DSCP profile i.e. four profiles total per IDU) MEF/RFC4115 based ”policing” (CIR/EIR/CBS/EBS) per QoS-class and optionally per VLAN For each egress port Queuing 4 or 8 classes 4xSP, 4xDWRR, SP+3xDWRR, 8xSP, SP+7xDWRR, 2xSP+6xDWRR, Shaping per class Buffer size setting per class Yellow/Green threshold per class Egress port shaping 802.1ag Service OAM (CC/LB/LT) Y.1731 PM (LM/DM) STP/RSTP, G.8032v2 ERPS (Ethernet Ring) 802.1AX, 1:1 LACP redundancy; RTA load balancing based on L2 (MAC, VID, TPID, port) or L3 (IP source and destination, both TCP/UDP port numbers), frame ordering preserved; maximum speed per stream is equal to single modem speed; Physical RTA: maximum speed per stream equal to combined capacity minus a small overhead Supported (optional clock module required) RFC4533 SAToP (MEF8) Link Loss Forwarding, Mirror/Monitor, Broadcast Storm Control, L2 Filter, Port Isolation Table 5. iPasolink 400 Ethernet-switch main characteristics 22 IDU CONFIGURATIONS Table 6 lists the available plug-in unit options. Type number Name NWA-055298-001 MC-A4 NWA-055300-xxx*) MODEM-A NWA-055303-001 NWA-055303-101 NWA-060926-002-01 Sumitomo SCP6G44-GLCWH NWA-060926-003-01 Finisar FCLF8521P2BTL NWA-055294-001,-002 NWA-055310-001 CBE-009983-001,-003 NWM-034915-001 NWM-034910-001 NEC-XCB-1023-0,4 NWA-055302-001 NWA-055302-101 NWA-055304-004 NWA-055304-104 GbE-A LX SFP Control unit with 16E1(MDR) + 2GbE(RJ45)+ 2GbE(SFP) – mandatory Modem can be installed in universal slots 1 to 4, optional. TNC connector (female) for the ODU-cable. Grounding connector. Modem power switch. XPIC-connectors. 512QAM supported HWversion 2.00 and later 2GbE(T) + 2GbE(SFP) interface card for slots 1 to 4, optional LX SFP Module 1000 Mbit/s GbE T (TRI) SFP Electrical GbE (TRI-MODE) SFP: 10/100/1000 BASE-T FAN-C PS-A4 136147-3 BLANK COVER BLANK COVER XPIC CABLE Fan unit, mandatory Power supply unit (one mandatory, second optional) SFP-port protecting plug Universal Slot blank cover (mandatory when Universal Slot empty) Power Supply blank cover (mandatory when PS not installed in slot) XPIC cable 40 cm, two cables per XPIC modem pair 16E1-A 16 x E1 interface card for universal slots 1 to 4, optional STM1-A NWA-055306-001 MSE-A NWA-055307-001 AUX-A NWA-055289-002 Description CLK2M-C STM-1 interface card for universal slots 1 to 4 Optical Interface(S-1.1)/(L-1.1) or Electrical G.703, optional PWE-card for universal slots 1 to 4, optional. For transporting E1 over Ethernet packets. Additional interfaces (ALM, EOW, NE2) , for universal slots 1 to 4, optional. Clock module, installed on the MC-A4 card, required for Synchronous Ethernet and SDH-demultiplexing. Optional. Can be retrofitted in the field. Table 6. IDU cards *) xxx = 001 (discontinued); 202 = ASIC version; 102 = PRTA version (required for L1 physical Radio Traffic Aggregation); 322 = unified version, available 9/2012. Limitation: the SFP modules installed in each MC-A4, GbE-A or STM1-A SFP port have to be identical or the right port empty. Third party SFP modules do not generate an alarm (note: FW version dependent) but correct operation is guaranteed only for an SFP delivered by NEC. 23 Figure 10 presents the plug-in unit configurations in the indoor unit and Figure 11 depicts the plug-in units. Figure 10. Indoor unit NWA-055268-001 and its ODU connection Figure 11. Universal Slot-modules/cards. Note: Modem-A module: the old HW-version has no ONLINE led. 24 PDH-INTERFACES The control unit (main card) MC-A4 and 16E1-A-card MDR68-connector and pin layout is identical with the Pasolink NEO HP AMR MDR68-connector. See Appendix B and the section on ”PDH provisioning”. MANAGEMENT AND AUXILIARY INTERFACES MC-A4- and/or AUX-A-card (optional) provide the following management and auxiliary interfaces (Table 7). Interface Description HK-ALM (IDU alarms and external inputs) OW (engineering order wire) IN OUT DSC (Digital Service Channel) DCN (Data Communications Network) MC-A4 (channels) 2 AUX-A (channels) 6 4 Plug for headset Push button for buzzer EXT IN/OUT V.11 1 - 1 - 2 2 - RS-232C LCT 2 1 - NMS 1 - NE1 1 - NE2 - 1 1 - 1 - USB EXT Clock IN/OUT Note 64 or 192 kbit/s synchronous/asynchronous asynchronous 10/100BaseT(X) DHCP server at 172.17.254.253 (fixed) 10/100BaseT(X) IP address configurable DCN: 10/100BaseT(X) IP address configurable User traffic: 10/100/1000Base-T 9.6 kbit/s RS-485 asynchronous IDU/ODU FW updates, configuration file backup/restore CLK2M-C module required 2 Mbit/s or 2 MHz Table 7. Other interfaces. The serial interface (V.11 and RS-232C) pin layout is presented in Appendix C. The external clock (EXT CLK) connections are included in the same connector but they are activated only when using the CLK2M-C module. 25 INDOOR UNIT CONFIGURATIONS Figure 12. Modem positions for various single and dual IDU setups Figure 12 presents a summary on possible modem positions when using a single or dual IDU setup. For additional detais, see the Ordering Guide. 26 ORDERING CODES See the Price List and the Ordering Guide for the ordering codes. PREINSTALLED LICENSES When agreed between the customer and NEC, the IDU may have all the licenses preinstalled. Certain functionalities are then always paid for and available for immediate use. Certain functions require additional payment before use. See the Price List and the Ordering Guide for details. In case of a missing license key, it has to be prepared and delivered by the factory for installation. The following serial numbers are required and are associated with the license key: - iPasolink 200: IDU serial number iPasolink 400: MC-A4 card serial number iPasolink 1000: serial number of TERM-M card SAFETY ISSUES The following presents some basic safety issues related to microwave installations. OPEN WAVEGUIDE AND OPTICAL CONNECTORS During the installation and operation it is important to remember at all times that any open microwave connection (waveguide or coaxial) will radiate microwave signals. Similarly, open optical connectors may emit invisible optical signals. These signals may damage the eye permanently if the connector is too close to the eye. The risk is a microwave-induced cataract or laser burn damage of the retina. The damage is similar to any burn damage and is caused by excessive heating of the tissue and occurs almost instantaneously. AVOID THE FRONT OF T HE ANTENNA One should avoid the intense radiation close to any radiating aperture unless the system has been designed for close human exposure. The appropriate national safety regulations have to be followed. Microwave antennas may cause radiation fields exceeding the regulated limits. Working in front of an antenna should be avoided when the transmitter is switched on. 27 RADIATION MONITORING DEVICES It is recommended that the installation crews use personal radiation monitoring devices. They are most useful when working close to high power HF/VHF/UHF transmitting antennas, in order to ensure that power has been switched off or reduced to a safe level. There are no cumulative long-term radiation effects known for non-ionizing radiation such as microwaves. The damage is caused only when the tissue temperature increases too much. Low level non-ionizing radiation below the excessive heating level is not known to cause any long-term effects. In this respect microwave radiation differs from X-ray, alpha, beta and gamma radiation, where no safe limit exists and it is the total cumulative dosage that matters. For monitoring microwave radiation the monitoring devices are not as useful as in case of HF/VHF/UHF radiation. The radiation is very local. When the upper body is in front of a microwave antenna, the monitoring device hanging on the belt may not see any significant levels even if the legal safe limit is locally exceeded. SAFETY DISTANCE FOR THE PUBLIC EXPOSURE The antenna must not be installed in such a place where it causes too high exposure to the public. The safe distance depends on the transmitter power, antenna size and frequency band. In case of iPasolink the safe distance is presented in Table 12. The calculation assumes maximum two (2) IHG ODUs per antenna and the assumed legal limit is 10 W/m2. The calculation is based on the “far field formula”, which is always on the safe side. F (GHz) 6 7 13 18 23 0,3 2,5 3,0 3,9 Antenna diameter (m) 0,6 1,2 1,8 3,6 7,2 10,8 4,2 8,4 12,6 4,9 9,9 14,8 6,1 12,2 7,8 15,5 2,4 14,4 16,8 3 18,0 21,0 Table 12. Safety distance in front of the antenna (metres). Two IHG ODU per antenna. The radiation is concentrated in front of the antenna aperture and the zone to avoid is a cylinder with the length indicated and diameter equal to antenna diameter. E.g. for a 7 GHz 3m antenna the safety zone is a cylinder 3m by 21m in front of the antenna. In practice some extra margin should be given, especially when it is easily available. In reality the far field formula overestimates the power density near the antenna. Therefore the distances are in most cases pessimistic, especially in case of large diameter antennas it may well be that the 10 W/m2 limit is not exceeded at any distance from the antenna. 28 One should be aware that the worst hot spot is usually 1 to 3 antenna diameter from the antenna aperture on the antenna symmetry axis. Another rule of thumb is that the maximum intensity is larger for a smaller antenna. The most dangerous “antenna” is an open waveguide (i.e. very small radiating aperture). The safety zone for a large antenna can be very long but the maximum intensity much lower than in case of a small antenna. INDOOR UNIT INSTALLATION The indoor unit is installed in a 19-inch or ETSI rack. The delivery includes brackets for both racks. There is an AMP-power connector included in the box but it is recommended to use a factory-made power cable. The indoor unit is cabled as usual (grounding, power cable, Ethernet, E1, SDH, management). It is not necessary to connect all E1 channels to the external connector and cross-connection frame: internal crossconnection can be used for E1 signals between modems. Same applies for Ethernet. VENTILATION iPasolink does not necessarily require any free space above and below the IDU due to cooling, but there has to be enough free space on each side of the IDU inside the rack, because the air intake and fan exhaust is on the side. Free space may be required when there is some other equipment requiring free space for cooling. Also cabling is easier when there is free space between units. Labelling of the modems is easier on the top side of the IDU. Therefore it is recommended to leave 1U of free space above and below each IDU. ENVIRONMENTAL REQUIREMENTS According to the specifications, the indoor unit operates within -5 to +50 degrees Celsius and the maximum non-condensing relative humidity is 90 per cent. The limits indicate the allowed short-term temperatures, e.g. during cooling system failure. Long-term average temperatures should be kept as low as possible, however, because a high average temperature will decrease the MTBF of any electronic equipment. The number of failures will typically double when the average temperature increases by 10 degrees. The indoor units should not be installed close to the ceiling: the distance should be at least one metre. Hot air currents should be avoided (eg. the exhaust of a base station cabinet fan). The cable entry points have to be sealed properly to prevent rain water entering the shelter. 29 POWER CONNECTION The indoor unit PS-A4 card -48V connector should be connected to a 10A fuse or automatic circuit breaker. This is sufficient when using a 2 x 1.5mm2 power cable and takes into account the fact that the current will increase when the battery voltage drops. Smaller fuses (6A) might blow when the IDU is fully equipped and the battery drains during a power failure in the site. Figure 13. Power supply connector Pins number 1 and 2 are internally connected on the equipment side (-48V) and so are pins 2 and 3 (0 V). It is not necessary to connect all four pins when using 2 x 1.5mm cables. Connect e.g. pin 1 and 4 only. The connector housing is Tyco Electronics 1-178288-4 which will accept four pieces of connector pins, type number 1-175218-2 (Figure 14). These connector pins (female) are for 0.5 to 1.3mm2 wires. The connector kit is included in the standard delivery. It is in practise suitable up to 1.5 mm2 fine stranded wires as well. ASSEMBLING THE POWER CABLE Normally a ready-made DC cable should be used. Field installation of the connector should be done only exceptionally. It is recommended to use the appropriate tool Tyco Electronics TE 91558-1. Please note that the insulation is attached separately from the wire (remove the insulation for 3 to 3.5mm only). It may be necessary to flatten the insulation with pliers or similar in order to push the connector pin inside the connector housing. Do not bend the guide blades. Each pin has to be pushed in until it locks audibly. Test each pin by pulling back; the connector must not move back from the housing. 30 Figure 14. Connector pin. The two guide blades (at the centre of the pin pointing upwards) should not be bent. Crimp the insulation blades and the conductor barrel only. ETHERNET CABLE CONNECTIONS The Ethernet cabling is done in the usual manner: electrical using Cat6 cables and optical using LX-type cables with LC-connectors. Alternatively SX-type SFPs are available. When inserting the SFP modules make sure that the module is locked in place (keep the latch in the locked or up position). Remove by pressing the latch fully down until the module is released. Never try to pull the SFP out when the latch is not pressed fully down. All optical connectors should be cleaned using a cleaning tool. Empty connectors have to be protected with plugs. PDH CONNECTIONS There are several types of ready-made E1 cables available (8 channels and 16 channels), one end with MDR68, the other end without any connector or with a connector suitable for a I/O-board. Please consult the price list. ODU INSTALLATION iPasolink uses frequency division duplex and therefore ODU is always either a LOW or HIGH version working on the same sub band. The LOW version has the transmit frequency lower than the receive frequency and HIGH version is of course the opposite. Each hop has to have one HIGH and one LOW type ODU of the same sub band. Moreover, the correct site has to use HIGH as instructed by the frequency planner (given in the 31 license). Note that all ODUs on the same site have to be either HIGH or LOW, if they use the same frequency band. The ODU version is indicated as HIGH or LOW on the box and on the ODU label. Andrew antennas are installed on a steel tube with outer diameter 48 to 115 mm (0.3m and 0.6m), 65 to 115mm (0.8m) or 115 mm (1.2m and larger). Aerial Oy antennas use 100mm installation tubes. The ODU mounting brackets for separate installation are designed for a tube of 48 to 115 mm outer diameter. 6 GHZ ODU WITH STANDARD WAVEGUIDE 6 GHZ ODU may use either N-type coaxial or PDR70 type waveguide interface. It should be installed separately. An installation bracket without any adapter is required for the ODU. Either a coaxial cable or flexible wave guide is installed between the ODU and a separately installed antenna. In case of the waveguide ODU version with PDR70 the flexible and twistable waveguide should have a UDR70 flange at the ODU end. The gasket (O-ring) has to be installed for weather-proofing. The waveguide should be attached at the middle in order to avoid vibration damage caused by wind. The attachment method must not change the shape of the waveguide, the bending radius has to be sufficient and twisting should be minimized. Note. If a “pressurized” e.g. a PDR-flange must interface another identical flange, then a double thickness gasket (O-ring) is required or at least two normal-size gaskets are needed. Usually PDR will interface to UDR with a normal gasket. Figure 15. ODU 6 GHz with standard IEC waveguide flange. Mounting bracket without adapter. 32 In case of N-type coaxial ODU, the interconnecting cable would be N-type and the antenna would need to have either an N-type connector or to be equipped with a N to PDR70 adapter. SEPARATE INSTALLATIO N OF 7 AND 13 GHZ DIRECT MOUNT ODU The “antenna direct mount” type ODUs for 7 GHz and 13 GHz are possible to install directly to the antenna using the NEC proprietary antenna interface. It is also possible to use a separate installation using a waveguide. The ODU installation bracket will then have an adapter from NEC interface to the appropriate IEC standard waveguide interface. 7 GHz uses UDR/PDR84 flanges and 13 GHz uses PBR/UBR140. See Figure 16 for the 7 GHz case. Again, UDR to PDR or PBR to UBR joints should be used with the suitable gasket or O-ring for weather-proofing. Figure 16. 7 GHz separate mount using a direct mount ODU and mounting bracket with adapter DIRECT MOUNT INSTALLATION In the 7 GHz bands and higher, the standard installation method is to use e.g. Andrew antennas with an integrated NEC proprietary antenna interface, which includes the four attaching holes and the hole for the guide pin etc. See Figure 17. The antenna is fixed to the installation tube and the direct mount type ODU to the antenna. 33 Figure 17. 13 GHz ODU attached directly to a 0.6m antenna. NHG type ODU; the IHG antenna interface is identical. The antenna delivery includes two different O-rings. For direct mount, the larger O-ring has to be used. The smaller one is for attaching a flexible waveguide in a separate installation. Both O-rings must not be used. Figure 18 below depicts the antenna flange. The inner groove is for the PDR-flange (used for separate installation). The larger outer groove is for the direct installation. Groove for the large O-ring for direct mount installation method. O-ring (gasket) for the IEC standard flange. Figure 18. Flexible waveguide for separate installation uses the inner groove and smaller O-ring. Direct mount installation uses the larger O-ring in the outer groove. 34 Figure 19. Changing the polarization. Details vary depending on the antenna version. In order to change the polarization of the antenna, the antenna feed has to be turned by 90 degrees. The feed screws are opened slightly to allow turning of the feed. Note: when the waveguide opening is horizontal (broadside up) the polarization is vertical. Figure 20. Changing of ODU polarization. The ODU has to be turned by 90 degrees so that the waveguide opening is aligned with the antenna opening. In order to fit the antenna, the polarization guide pin has to be moved to the other available position marked with V (for Vertical) or H (for Horizontal). Misalignment of the waveguide opening 0 to 90 degrees will cause additional loss of 0 to 40 dB. ODU CABLE INSTALLATION The ODU cable is typically similar to mobile base station antenna feeder, e.g. Draka ½ inch cable (RFA ½ -50) with suitable high-quality water resistant connectors. Both ends are normally fitted with a flexible tail cable with high-qaulity water-proof connectors. 35 The maximum cable length when using the above Draka cable as an example is about 500m, which includes an allowance for the higher per unit attenuation in the tail cables. Cables should be marked as required by the tower/shelter owner. Cables should be attached using proper permanent cable brackets – not temporary plastic cable ties. The minimum bending radius should be observed (e.g. RFA ½ - 50: 70mm). The cable outer conductor must not be deformed by the cable brackets. One well-known installation fault is a periodic deformation of the cable causing multiple reflections, signal distortion and bit errors. CABLE CONNECTORS Cable connectors have to be installed to the cable following the manufacturer’s instruction strictly and using the appropriate tools. The connector has to be sealed as recommended to the cable jacket using self vulcanizing rubber tape or a heat shrink tube with melting glue. Connectors which are installed improperly may be destroyed by moisture and electrochemical corrosion within a few months. The connector has to be absolutely dry when installed to the cable and also when the actual connection between the two connectors is made. The connector type has to be chosen so that the connection is water-proof without using any external seal (rubber tape) covering the two connectors. Taped connections are difficult to check for tightness of the connection between connectors. Rubber taping of the connection is thus not recommended. GROUNDING OPERATOR’S OR SHELTER/TOWER OWNER’S GROUNDING INSTRUCTIONS AND LOCAL REGULATIONS ARE TO BE FOLLOWED. GROUNDING OUTSIDE The ODU should be grounded to the tower grounding wire using 16 mm2 or larger copper cable. The size of the grounding terminal screw is M4 (Metric 4 mm). A suitable cable lug (e.g. 16-5.5, tinned copper) should be used. The connection to the tower grounding wire should be done using an appropriate C-type connector (Cu-Cu or Cu-Fe). In case of a roof-top installation, the grounding should use a 16 mm2 or larger copper cable from the ODU ground terminal directly to the main ground bar of the building to the nearest ground wire of the lightning protection system of the building to a TV common antenna system ground wire provided that it is minimum 6 mm2 Cu and continuity to the main grounding bar of the building is verified by measurement, directly to the main grounding bar of the equipment room where the IDU is installed. 36 Grounding wires should be installed as straightforward as possible, avoiding bends and loops GROUNDING IN THE SHELTER Grounding of the lower end of the ODU cable should be done at the connection between the ½-inch cable and the tail cable as close as possible to the wall feed-through point to the nearest grounding bar or wire using as short 16 mm2 Cu cable as possible. The length of the tail cable should be suitable so that the grounding point is close to the outer wall. The indoor unit should be grounded using the grounding connector of the modem to the grounding bar of the rack. Note that grounding using the rack screws is not reliable as the rack maybe painted using nonconducting paint. The rack grounding bar should be connected to the shelter grounding bus. All grounding wires should be as short as possible without any unnecessary bends or loops. If the grounding wire is too long, it has to be cut to suitable length. Coiling the extra length of wire is equivalent to leaving the grounding wire disconnected due to the inductance seen by lightning currents. SUITABLE GROUNDING CONNECTORS Tyco Electronics connecotr types: C-LOK 1-83016-0 C-LOK 0-81713-3 C-LOK 0-83713-1 C-LOK 0-81663-1 C-LOK 0-81663-6 C-LOK 0-81663-5 Cu16-Cu16 Cu16-Cu50 or 3/8" grounding rod Cu16-1/2" grounding rod Cu16-Fe 7*1.20 tai 7*1.57 steel wire Cu16-Fe 7*2.12 25mm2 steel guy wire Cu16-Fe 7*2.44 35mm2 steel guy wire Ensto C-connector (crimp connector) SE 36 Cu 16...25mm2 - Cu 16...25mm2 Ensto connector with a tightening nut SE 12.1 10...70 mm2 - 10...70 mm2 IDU AND CABLE LABELLING Labelling should follow operator’s instructions. OVERVOLTAGE PROTECTION There is no requirement to install any overvoltage protection devices to the IDU/ODU cable. Proper grounding should ensure that excessive potential differences do not occur. 37 LOCAL MANAGEMENT MANAGEMENT TOOL The indoor unit is managed using a PC and a standard web browser. Note. The previous generation (Pasolink NEO) LCT and PNMTj software are not compatible with iPasolink nor are there any such versions available. RECOMMENDED BROWSER Firefox is the recommended browser, because the ”Menu Bar” of the web page shows the FW-version, the site name and the modem IP address. Internet Explorer (IE9) does not show these labels, at least not when using the browser with default settings. Firefox normally works with the default settings, but it is advisable to set (Tool Bar) Tools -> Options, ”Always ask me where to save files” so that downloaded files can be saved directly to the proper folder. It may be necessary to change the security settings of the browser to lower level. In case of IE the ”medium-high” level normally works. Firefox should work with the default settings after the standard installation. LOCAL CONNECTION The PC is connected to the LCT port of the IDU using an RJ-45-cable. The LCT port contains a DCHP server and web server. The PC LAN card should be configured to obtain the IP address automatically. Port name Port IP address User name Password Figure 23. PC is connected to the LCT port using a LAN cable (RJ-45). LCT 172.17.254.253 Admin 12345678 38 When the DHCP server has given the LAN card an IP address, the default gateway indicated for the LAN card is the LCT port (and the web page) address. The address is easy to check by running cmd and typing ipconfig. If necessary, ipconfig -release and ipconfig -renew should get the proper address. Alternatively disable and enable the LAN card of the PC using the Control Panel (Windows 7). REMOTE LOGIN USING THE BROWSER The IDU can be managed remotely in the same way as locally (but with some limitations in allowed operations). The IDU need not be attached to PNMSj or MS5000. When using the NMS port for logging in, use the NMS port address if the IDU Bridge1 address is unknown. Then check the local and remote IDU Bridge1 addresses using the management interface and use the Bridge1 address to log in directly to the desired IDU. LOGIN WINDOW Figure 24. Login window. Default User Name = Admin and Password = 12345678 After logging in the main status page opens in a new window or (recommended) in a new tab, depending on browser settings. When the hop is operating properly (and the local and remote Bridge1 addresses are in the same subnet), the remote IDU can be logged in by using the pull down menu at the top of the main page. If necessary Refresh (F5) the page. The remote end will open in a new window or tab. Identify each IDU using the Menu Bar. 39 MAIN PAGE – MENU AND CURRENT STATUS The page opened shows the Menu tree and the Current Status of the IDU. Figure 25. Current Status –window shows the active alarms after pressing Refresh. In order to allow changing of the settings immediately, the status window is not updated until the Refresh is clicked (FW 3.00.37 and later). NAMING OF THE IDU AND MODEMS The IDU and modem ports should be named based on the site name and on the radio hop ID (e.g. opposite site name, hop ID) following operator’s conventions. The IDU is named separately from the modem ports. The alarms in the PNMSj are identified by the IDU name and e.g. Modem Slot1 (= first slot from the left). The IDU name is visible in the web browser Menu Bas (Firefox, see Fig. 25). The modem port name is visible in the LAN switch (Ethernet) settings. BASIC SETTINGS This chapter describes the minimum setting required to align the antennas and establish connection to the opposite end and establish connection with PNMSj. 40 Note: if suitable basic configuration files are first copied to each IDU, following the Quick Installation Guide (Appendix D) is sufficient. The basic configuration files should contain all the default settings for the operator. Then only those settings that vary from each NE to NE need to be changed during installation. PROVISIONING CLEAR If the IDU is not at the factory settings, it may be useful to return all Provisioning Settings to factory settings using Equipment Utility -> Shipment -> Shipment. This operation disables all modems and other cards and removes all settings under Provisioning. Note: e.g Network Management Configuration and Security Management settings (such as NMS port adresses and SNMP, NMS and NTP server addresses etc.) remain unchanged. Before the Provisioning Clear it is necessary to set the MAINT status on. Select ”Provisioning Clear”. The IDU will be reset, and it is necessary to wait a few minutes for the reset to complete. The operation is finished when the MAINT led stops blinking and LCT port is again operable. Note. Possible only locally using the LCT port. Not possible remotely using the NMS port. MODULE SETUP It is normally not useful to use the ”Easy Setup Wizard” because the detailed settings need to be changed anyway. Equipment Setup -> Equipment Configuration -> Setup Changes are made using the Setup button. The setting window shows the Current Setting and on the right the New Setting is used to input new values. Continue by clicking Next > and OK. 41 Figure 27. Equipment Configuration. Use Setup button to modify. NE Name – Give IDU name (e.g. Site Name – IDU – IDU#). Maximum 32 characters, no special characters! Element setting. Figure 27. NE Name. 42 Equipment Configuration – Select the cards (press Auto Detect), if necessary disable by selecting ”Not used” for cards that should not be used. Note that cards should not be removed physically due to EMC and IDU cooling reasons unless a blank cover is installed. Element setting. Figure 28. Enabling and disabling modules. MODEM/STM-1 SW/XPIC Configuration – Select proper setting (e.g. XPIC 1+0 tai 1+1). Element setting. 43 RADIO CONFIGURATION Equipment Setup -> Radio Configuration -> Setup Figure 29. Radio Configuration Setup The thin green frame in the left upper corner indicates which modem is being set up. Unfortunately the modem port name is not shown in this window (shown in the Ethernet settings only). ”ODU Information” shows the available settings of the ODU connected currently. New setting is used to input new values. Channel Spacing – Input the channel spacing (MHz) given in the frequency license. Element setting. 44 Reference modulation: This selection determines the maximum available power. In order to get maximum power at QPSK, select Reference Modulation = QPSK. Element setting. Note. The transmitter power depends on a) MTPC setting and b) current modulation. When the reference modulation is QPSK, the MTPC setting allows selecting the maximum power. But even with MTPC selected, the power is automatically adjusted slightly lower according to the current modulation automatically selected by AMR. In other words, MTPC includes an automatic TX power fine adjustment part. EXAMPLE License allows -6dBW or +24dBm. If the reference modulation is selected as 256QAM and adaptive modulation is used, the maximum MTPC setting is +19 dBm. When the hop fades, the modulation is changed all the way down to QPSK, but nevertheless the power is limited to +19 dBm. If QSPK is selected as the reference, the maximum MTPC setting is +24 dBm. The hop will then tolerate 5 dB more fading at QPSK (will use +24 dBm), but will normally (no fading) use 256QAM at +19 dBm. Radio Mode – Select High Capacity, unless otherwise instructed. This setting selects the error correction code settings. High System Gain will give about 1 dB more fade margin, but will reduce the capacity by several Mbit/s (shown in ETH Bandwidth). This setting has to be the same at both ends of the hop. Hop setting. E1 and STM-1 Mapping (CH) – Capacity reserved for E1- and STM-1 -channels. Change under AMR / Radio Mapping Configuration. Hop setting. ETH Bandwidth (Mbps) – Indicates the remaining available Ethernet capacity (Mbit/s) for the reference modulation. Radio Mode and E1/STM-1 mapping setting will change this value. TX and RX Frequency (MHz) – Set the frequencies given in the license exactly. Element setting. If the setting fails, check that the ODU sub band is correct and that the HIGH/LOW version is correct. Check the ODU information or Inventory. Verify that the correct modem is selected for configuration. Note. Setting of the frequency is not possible without a proper ODU connected to the modem. Frame ID – default 1. Frame ID has to be identical for both modems at each end of the radio connection. Frame ID is checked in order to prevent communication with a wrong modem in case the remote transmitter fails or fades away. Using different Frame ID settings may be necessary in a hub with several iPasolink ODUs using the same channel. XPIC modems using the same channel must have different ID values. Default = 1. TX Power Control – Select MTPC (fixed power excluding AMR adjustment), unless otherwise instructed. Default setting = MTPC. Automatic ATPC mode might be necessary for the remote sites connected to a hub, in order to prevent excessive interference from other hops re-using the same or adjacent channel. 45 Radio Traffic Aggregation – aggregating the Ethernet capacity of two modems operating on the same hop. Hop setting. Figure 30. Radio Configuration changes confirmed by OK. Settings continue with AMR settings. 46 ADAPTIVE MODULATION RADIO (AMR) Equipment Setup -> AMR/Radio Mapping Configuration, Setup Figure 31. Adaptive modulation (AMR) settings. Example: license allows 32QAM, 16QAM and QSPK. If antennas have not been aligned, select AMR Non Operation. Adaptive modulation changes the transmit power slightly which would cause problems during the alignment. After the alignment is ready remember to select AMR Mode (Used) for the appropriate modulations. Input the number of E1 and STM-1 channels for each modulation level. Figure 32. Adaptive modulation E1- and STM-1 settings. 8 E1 channels enabled. 47 NETWORK MANAGEMENT (NMS) SETTINGS Figure 33. Typical NMS subnet The root element (Root NE) is the indoor unit where this cluster is connected to the NMS DCN using the NMS port (or in band connection). The rest of the cluster is connected internally or by connecting NMS ports together at the intermediate sites. The relevant settings are under Network Management Setting -> General Setting (Detail) Note. Network Management Configuration -> General Setting. Ignore this. All settings are under General Setting (Detail). 48 Figure continues on the next page. 49 Figure 34. NMS settings. NE2 Port Setting: NE2 is on the AUX-A card, a serial port used when interfacing some legacy equipment. Default Not Used. In band Management VLAN Setting - Default “Not Used”. The settings here assume that NMS port is used for management. Default setting. Ethernet Port Setting NMS Root Element select Used, Auto Negotiation: Enabled and Discovery Usage: Used. LLDP Mode: Standard. This setting is correct for root elements. Other elements. Normally NMS port is Not Used unless two IDUs are interconnected. Modify default setting for normal elements. Element setting. NMS port can be used for testing the connection to NMS server from the remote sites. The PC should be given a suitable IP address from the same subnet as the iPasolink cluster by the network administrator. 50 Note that the LCT port can also used for pinging the NMS server using the standard PC settings for local management, i.e. using the local IP address given by the DHCP server of the LCT port. NE Branch Setting – If the network elements are in a different subnet than the NMS port or if the NMS port or NE1 port is used for connecting another subnet then the element is configured as a router. Two or more Bridges (Bridge1, Bridge2 etc) are configured, these are the ports of the internal router, each having an address within a different subnet. Default Gateway. This is the gateway port of the elements’ subnet that is used to access the NMS server. In the root element where the NMS port is in a different subnet, it is the IP address of the nearest DCN router where the NMS port is connected. In such a subnet the normal element default gateway is the root element Bridge1 address (it is the nearest router for those elements). Element setting. Bridge: if the element uses two or more branches (i.e. the element acts as a router), the NMS port is Bridge2 and the modem is Bridge1. Note that the PNMSj server is looking for network elements in the Bridge1 subnet. Element setting. Bridge No., using the link 01 Bridge 1 i.e. modem IP address is set according to the instructions of the DCN designer who manages the addresses. Using the link 02 Bridge 2 i.e. the NMS port address is set, etc. Element setting. NE1 or NMS or MODEM: the link is used to select the Bridge number assigned to that port. First set up the IP addresses for the bridges and then select the bridge number for each port. M-Plane Bandwidth Limitation: use ”Disable”, unless otherwise instructed. This setting limits the management traffic in the radio, if necessary, to provide more capacity to the user traffic. Default setting. M-Plane Priority: Default: QoS = 7, which means that management traffic has the highest priority. Default setting. NMS Port Setting : In the root element, select ”Connect NMS port to NMS” = ”Yes”. Default setting for the root element. In non-root elements select ”Connect NMS port to NMS”= ”No”. Element setting. Note: if there is a Pasolink NEO cluster behind the iPasolink cluster connected to the NMS port, select ”Connect NMS port to NMS” = ”Yes” for that element. LCT Port Setting Restrict LCT Connection: Select “Any”. LCT port can access the whole network (“Local” would prevent the management of other elements than the local IDU). Default setting. Equipment Setup -> Network Management Setting -> Routing Setting There should be no need to change these settings. 0.0.0.0 associated with the Default Gateway IP address should be automatically listed. Default setting. 51 Equipment Setup -> Network Management Setting -> IP Access Control Setting Do not change the settings. Empty list means that any PC connected to any IP address can manage the element remotely. Default setting. Equipment Setup -> Network Management Setting ->Equipment Cascade setting Do not change the settings. (Explanation to be added later). Default setting. MODEM SETTINGS MODEM PORT NAME Provisioning -> MODEM Function Setting -> MODEM Port Setting Name the modem port according to the operator rules. E.g. Site name – Opposite site name – Hop ID. MAC Header Compression: default is ”Disable”. As explained in the chapter about the radio capacity, MAC header compression would improve the packet rate and link throughput when the average packet size is very small (less than 500 octets). Note: L1 compression is always used and is not affected by this setting. Figure 35. Modem port name and MAC header compression. TRANSMITTER POWER SETTING Provisioning -> Modem Function Setting -> TX Power Setting Note. ATPC/MTPC mode selection is under Equipment Setup -> Radio Configuration -> Setup- > TX Power Control. Default selection MTPC. MTPC TX Power: set the maximum power (in dBm) allowed in the frequency license. Element setting. This setting defines the maximum power used for the reference modulation. When using AMR and MTPC, the actual transmitter power will be lower, if the AMR selects a higher modulation format than the reference. 52 Figure 36. TX Power Setting. In Fig. 36 the power setting can be set between -6 dBm and + 24 dBm. Please note that there is a dash ”-” between the values, not a minus sign. iPasolink power setting is made using real dBm units (decibel relative to 1 mW). For reference, the various units are as follows: 1W= 0,1 W = 0,01 W = 0,001 W = 1000 mW = 100 mW = 10 mW = 1 mW = +30 dBm = +20 dBm = +10 dBm = 0 dBm = 0 dBW -10 dBW -20 dBW -30 dBW Note. The previous generation NEC Pasolink NEO used power setting in “dB relative to the maximum available power”. RX Threshold: use the default setting -50 dBm. This is the target minimum received level, below which the opposite end transmitter power will be increased when ATPC is in use. This setting may need to be changed when this element is using MTPC and the opposite end is using ATPC and both without AMR. Asymmetrical ATPC/MTPC may be required in a hub by using ATPC at the remote sites, and MTPC at the hub site. Default setting. SYNCHRONIZATION SETTING Provisioning – Equipment Clock / Synchronization Setting -> Equipment Clock Setting -> Modify/Edit This setting defines the timing source for the IDU so that there is no timing loop. The general rule is that one end of the hop is Master and the other end is Slave. More complex situations (chain, ring) need to be considered separately. (It is also possible that all network elements are Slaves, when the Clock Card option is used) Master is synchronized to the internal free-running clock of its Main Card (Internal tai Freerun). Slave is then synchronized to the Master using the received signal from radio/modem towards the Master. 53 If both ends are Master-Master or Slave-Slave, the connection will be unstable: errors and/or Unlocked alarms. The element management may report ”Communications Error” when using the web browser. Note. If a chain contains several iPasolink sites and the intermediate site is using a single IDU (two modems per IDU), then the first IDU of the chain on the core network side should be Master and all the other IDUs Slaves synchronized to the modem towards the Master. In this case there are several Slaves connected to each other, but the timing is nevertheless derived indirectly from the Master IDU. SETTINGS WITHOUT THE CLOCK CARD –OPTION Without the Clock Card –option the setting is very simple, see Fig. 37-38. Three alternatives are available Internal / MODEM/ Auto. Select Internal (= MASTER) at the other IDU and Modem (=SLAVE). Chain of IDUs; see the note above. Element setting. Figure 37. Slave setting without the Clock Module Auto setting is used for the slave e.g. in a ring in order to select the clock automatically from the two directions. 54 Figure 38. Master setting without the Clock Module. SYNCHRONIZATION SETTINGS WITH THE CLOCK MODULE The settings are presented in Fig. 39 and 40. Figure 39. Master setting with the Clock Card -option. Equipment Clock Setting – MASTER Equipment CLK Mode: Master Clock Source Selective Mode: QL Mode (Quality level). Equipment Clock Setting – SLAVE Equipment CLK Mode: Slave 55 Clock Source Selective Mode: PL Mode (Priority Level). (QL Mode could be used as well). Select No.1 Line CLK (MODEM), and the Slot number where the modem towards Master is installed and select Priority Level = 1. In case of 1+1, select the two modems for Priority level 1 and 2. Figure 40. Slave settings with the Clock Card –option DATE AND TIME SETTING The system may or may use NTP for the date and time setting. In any case the Date and Time should be set initially, in order to time stamp the event logs correctly. Equipment Utility -> Date / Time Setting -> Modify Figure 41. Date and time setting. Copy the PC time by selecting Display PC Time and press OK. Verify that the Time Zone is the same as is used in the NMS server. Element setting. 56 NETWORK MANAGEMENT SECURITY SETTINGS User Account/Security Setting -> Security Management -> Service Status Setting Figure 42. Status of the management related services ”Service Status” window should look like Figure 42. Other services should be running except for the SFTP and HTTPS stopped. Figure 43. SNMP service settings 57 Figure 44. SNMP Community settings (no access control). SNMP Community. Default setting: public/Admin/Access Control Disable (0.0.0.0/0.0.0.0). The first line can be edited using the link 1. The Community name has to be the same as in the PNMSj settings (public). Access Level = Admin. Source IP and mask 0.0.0.0 means that the Access Control is Disabled). Default setting. If access to the element has to be limited from a single NMS server IP address only: Source IP Address = PNMSj-server IP address and Subnet Mask = 255.255.255.255. (Note! This is not the subnet mask where the NMS server is situated but the mask for checking the address validity. Full mask checks all bits in the address). It is possible to give Source IP Address = subnet address and the Subnet Mask = subnet mask. In that case the server may have any address within the specified subnet. Example: Source IP Address = 192.168.180.0 and Subnet Mask 255.255.255.0 => SNMP-message may originate from any address within 192.168.180.1 to 192.168.180.254. SNMP Trap Entry. Normally empty, unless SNMP traps (alarms) are to be sent to another destination besides the NMS server. Default setting. 58 NTP SETTINGS FOR THE ROOT ELEMENT User Account/Security Setting -> Security Management -> Service Status Setting Figure 45. NTP settings for the root element when the NTP server is at 192.168.180.36. Most accurate time stamping of the events and logs etc. requires that an NTP server is available for the root elements. Figure 45 shows the settings for the root element. It is both a Client of the NTP server and a Server for the normal elements. Unicast mode is used (i.e. using IP addresses to communicate). NTP Version has to be the same as in the NTP server. If there is no NTP server available in the management network, set the root element NTP Client Mode = Disabled. In that case the root element clock (date and time) will slowly drift but the whole subnet (root and its normal elements) remains locally synchronized. 59 NTP SETTINGS FOR NON-ROOT (NORMAL) ELEMENTS User Account/Security Setting -> Security Management -> Service Status Setting Figure 46. NTP settings for normal elements. NTP server is the root element modem (Bridge1) IP address. For other elements than the root element the NTP Server Address is the root element Bridge1 address. The NTP Server Mode is now Disabled. Note. In a small network it would be possible to define all network elements as NTP Clients only and specify the same NTP server for all elements. But in a large network it is better to use a hierarchical system where only a limited number of root elements communicate with the NTP server and most elements get the time from a lower level server (the root element in this case). The polling interval can then be much shorter (more accurate clock) without overloading the NTP server and the DCN. 60 OTHER SERVICES User Account/Security Setting -> Security Management -> Service Status Setting Figure 47. FTP, SFTP, HTTP and HTTPS service settings Note that the HTTP service should never be disabled as the web interface will be disabled and restoring this setting would be impossible remotely. The SFTP and HTTPS services should be Stopped (either HTTP or HTTPS should be running, not both). Default settings. Figure 48. FTP settings. 61 ANTENNA ALIGNMENT The basic settings described in the previous chapters should be done before the antenna alignment. Before the alignment some temporary settings are required for correct receive level indication. ALIGNMENT SETTINGS If the element is already connected to the NMS server, set Maintenance on (Current Status top of page). This will record in the logs that some maintenance operation is going on causing RX level changes and alarms Under Equipment Setup -> Radio Configuration -> Setup verify that the reference modulation is set QSPK Check that the power setting is manual: Equipment Setup -> Radio Configuration -> Setup -> TX Power Control = ”MTPC”. Under Equipment Setup -> AMR Configuration set AMR to (”Non Operation”). Set the maximum power under Provisioning -> Modem Function Setting -> TX Power Setting. These settings have to be done at both ends of the hop before the alignment. Note that the local settings affect the RX level measurement at the remote end. Remember to restore the correct settings after the alignment. Note: depending on the local regulations, the use of maximum power during the alignment may be prohibited. In any case the risk of interference to another link is minimal, when the alignment is done quickly. The victim receiver must experience a rare deep rain or multipath fade during the alignment in order to cause problems and therefore increasing power for a short period of time should not cause any problems to other hops. RECEIVER LEVEL MEASUREMENT The ODU has an F-type female connector for the level monitoring. The voltage is available at all times. There is no setting to switch the voltage off or on. A typical calibration curve is presented in Figure 49. Before climbing to the ODU it is wise to check the target voltage level. E.g. -45 dBm equals about 2,8V. 62 Figure 49. Typical connector voltage vs. receiver level at the ODU antenna port A typical mistake during the alignment is to find the first side lobe of the pattern. Note that the side lobes are circular around the round main lobe, when looking behind the antenna. The minima between the maxima are also circular. See Figure 50. Figure 50. Antenna lobes are circular. First side lobe may be confused with the main lobe. 63 While aligning the antenna at one end, the other end antenna must not be moved. After the main lobe has been found at one end the other end is aligned. Finally the correct level is verified at both ends. The alignment is correct when there are two lower side lobes next to maximum both in the elevation and in the azimuth direction. HOP ATTENUATION VERIFICATION Under Metering -> Current Metering the received level is indicated in dBm as well as the current transmit power in dBm. Verify that the difference between the remote transmit power and the local received level is the same as in the hop calculation. The difference (hop attenuation) should be correct within a few dB (+-2 dB). If the hop attenuation is not correct within the tolerance, check first the weather conditions. During rain (typically >10 GHz) or clear air multipath fading (typically < 13 GHz and long hop > 20 km) the attenuation may be temporarily very high and unstable. If the temporary weather is not the reason any permanent cause (obstacle, reflection, antenna misalignment) has to be removed. Consult with the hop planner. Too high hop attenuation means that the fade margin is not as good as planned and the availability and error performance targets will not be met. Restore the correct settings if they were changed for the alignment. Reset the PMON counters and clear the event logs. Maintenance Control/PMON/RMON FDB Clear and Equipment Utility/Log Clear Function. MANAGEMENT NETWORK The management system for NEC Pasolink/iPasolink called PNMSj. Alternatively the more generic MS5000 can be used. The DCN is based on Ethernet/IP/TCP/UDP/SNMP. Each cluster of radio links is usually connected to the NMS DCN at one IDU (the root element). The root element is connected to the DCN using the NMS port or using a VLAN in the traffic port (in-band connection). The other elements are connected to the root element or other element over-the-air or using NMS/NE1 to NMS/NE1 Ethernet cabling between two IDUs at the same site. 64 Figure 51. Management network using a dedicated IP DCN network Figure 52. Cabling within a site with three separate IDUs In Figure 52 the connection is between NE1 (has to be configured for NMS use) and NMS or between two NMS ports. Note. If one of the IDUs is Pasolink NEO, its LLDP has to be enabled and the iPasolink IDU connected to the NEO using the NMS port has to have “Connect NMS port to NMS” set to “Yes”. In case of iPasolink 400 single IDU repeater (all three modems in a single IDU) the NMS connection is internal and all modems are connected to Bridge1. 65 DCN OVER PDH/SDH If there is no Ethernet/IP DCN network available to any station in the iPasolink cluster, it is possible use PDH network for DCN (“Ethernet over PDH”). At least one E1 should be dedicated to the NMS traffic per iPasolink cluster. RAD Egate with remote RICi units has been used successfully for this purpose. Egate has an Ethernet interface to the NMS DCN and an STM-1 interface to the SDH/PDH network. One E1 carries the NMS traffic through the network to the remote cluster where an RICi unit is used to convert the E1 back to an Ethernet port connected to the root iPasolink NMS port. MANAGEMENT USING METRO ETHERNET VPLS SERVICE One possible solution to connect the DCN to iPasolink is to use the Metro Ethernet to carry the DCN as a VPLS service. This solution will keep the DCN network separated from the Metro customer traffic. Figure 53. Management connection using VPLS over Metro network The advantage of using VPLS (as opposed to point to point VPN) is that a single Metro port at site X may serve many tens of microwave sites (site A, B,.. etc). 66 PROVISIONING PDH Provisioning -> E1/STM-1/Cross Connect Setting -> E1 Port Setting Figure 54. E1 ports have to be enabled at the main card (MC-A4) connector. Modify button allows to enable the MDR68 connector E1 ports to be used. Select the impedance (usually 120 ohms symmetric pair connected to the external cross-connect frame). The ports can be named if necessary. Report means that if a port is Not Used but there is an E1 signal received, Usage Error is reported. SEE APPENDIX B FOR THE MDR68 PIN LAYOUT. 67 E1 channels have to be enabled in the modem (in the AMR settings) and the connector ports enabled in the connector as shown above. In addition, these two have to be cross-connected together. Modem channels can also be connected to another modem so that these E1s are not available at the external connector but are transmitted directly to the next hop. Provisioning -> E1/STM-1/Cross-connect Setting -> Cross Connect Setting -> Add Figure 55. Summary page, 8 x E1 channels of the modem connected to the first 8 channels of the MDR68-connector New cross-connections can be created or removed (Add/Delete). Figure 56. E1 cross connect setting 68 Select one channel on the Edge A side and another on the Edge B side and press OK. Repeat for additional connections. Block selection is also possible. Element setting. Note. Under Equipment Setup -> AMR/ Radio Mapping Configuration the number of E1 channels carried by the radio were set for each AMR level. If the modem E1 channel setting is changed then the extra cross connections are removed automatically. Hold-off Timer Setting. Default is ”Disable”. Default setting. AMR Linkage shows how many E1 channels are available at each modulation level. Figure 57. AMR E1 priority status. Lower channel number has higher priority. 69 ETHERNET SETTINGS Provisioning -> ETH Function Setting The Menu contains numerous L2 switch settings under Eth Function Setting. This chapter describes the most common settings only. Interface numbering Ethernet ports are identified by the main card (MC-A4) or by the card type/slot number (GbE-A/Slot 1) as well as the port number (Port01). Positions and ports are numbered from left to right. Port 1 and 2 are electrical and port 3 and 4 are SFP slots. Limitation: each card (MC-A4 or GbE-A) accepts only one type of SFP at a time. Port 3 and port 4 have to have the same SFP inserted or port 4 has to be empty. Bridge Setting Figure 58 shows the recommended settings which should not be changed. Note. The VLAN Mode (802.1Q tai 802.1ad) has to be identical in all IDUs in a cluster. Differing settings will prevent remote management and connection to NMS. Figure 58. L2 switch basic settings. ETH Port Setting Ethernet ports can be opened (Enable) and removed from use (Disable). The ports can be named. 70 Figure 59. In this figure MC-A4 2nd port has been given a name ”TRUNK” and it has been enabled. The cable is disconnected (Link Down). The correct Ethernet settings depend on the external equipment settings. Figure 60. GbE settings. Note. Optical SPF allows selecting ”Electrical” but that will cause an alarm. VLAN SETTINGS VLAN Setting ”VLAN List” tab: create here first the VLAN ID numbers and names. Element setting. 71 Figure 61. VLAN settings. The VLANs can be assigned to ports in the VLAN Setting tab. Figure 62. Example VLAN settings. Each external port has a tunnel VLAN and the modem port allows traffic of these VLANs (as trunks). VLAN Port Type setting selects how the incoming (Ingress) and outgoing (Egress) frames are handled. The VLAN port types are explained first. Type selection available depends on the BRIDGE (VLAN) mode. The simplest way is to use the 802.1q –mode and tunnelling. The remote site has one or more physical ports each with a single VLAN tunnel. In the modems and at repeater sites the VLANs are forwarded using trunk ports. The traffic can be aggregated to single trunk port or each tunnel can be terminated in a separate physical port (see Figure 65 – 66). 72 BRIDGE MODES (802.1Q AND 802.1AD) Bridge mode (aka VLAN mode) is selected under Bridge Setting. The VLAN port types are as follows: 802.1q type Access port Tunnel port Trunk port (modem port is trunk always) Ingress port action Adds the assigned tag if no incoming tag. Accepts tagged frames with the assigned VID only, does not add double tag. One VID per access port. Adds the assigned tag always (double tagging if tag already). Adds a double tag over an assigned tag. One VID per tunnel port. Accepts only assigned VIDs. Does not add any tag. Several VID per port. Egress port action Will not forward the frame unless the assigned VID. Always removes the tag. Forwards only frames with the assigned outer tag VID. Removes that tag always. Forwards only frames with the assigned tag VID. Does not remove the tag. Table 13 . 802.1q –mode. Ethernet frame TPID = 0x8100. 802.1ad type C-Access port C-Bridge-port S-Trunk port (modem port always) Ingress port action Adds always the assigned S-VID tag. Accepts untagged frames. Drops frames with a wrong S-tag. One S-VID per port. Assign one S-VID and several C-VID. Untagged frames dropped. Accepts frames with assigned CVID and adds the S-VID tag. Accepts assigned SVID outer tag with any CVID tag. Accepts only double tagged frames with the assigned S-VID-tag. Never adds an S-tag. Several S-VID per port. Egress port action Will not forward the frame unless the assigned S-VID. Always removes the S-tag. Forwards only assigned S-VID double tagged frames. Removes the Stag. Egress frame may only have the assigned C-VID. Forwards only assigned S-VID tagged frames. Does not remove the Stag. Table 14. 802.1ad mode. Ethernet frame TPID = 0x88a8. C-tag TPID = 0x8100. 73 It is possible to create several VLAN ports in the same physical port with certain limitations. As an example, 802.1q trunk-port (VID= 100) and access-port (VID=200) may coexist in an Ethernet port. The port will then accept VID=100 tagged frames as well as VID=200 tagged frames. All untagged frames will also be accepted and a tag with VID=200 is added to them. Modem ports can only use trunk VLANs. SAMPLE VLAN SETTINGS Provisioning -> ETH Function Setting -> VLAN Setting -> VLAN List ”+ Add VLAN ID”. Create VID = 100, name ”Elisa”; VID = 300, name ”Sonera 3G”; VID = 400, name ”Sonera 4G”. See Figure 63. Figure 63. VLAN List. Now assign these VLAN IDs to Ethernet ports, type ”802.1q Tunnel”. Add all the VLAN IDs to the modem port (Trunk). Figure 64. VLAN settings in a sample case. 74 Any frame (untagged, single tagged, dual tagged or multiple tagged) arriving at a Tunnel port will be added the assigned VLAN ID and be sent to the opposite end over the modem port. If the opposite end has a fully identical VLAN setup, the traffic will egress at the same port as the original port without the added tag (same frame as the original frame with any customer VID). Internal VIDs inside the hop are invisible to the outer world and no co-ordination with the customer VID is required. Figure 65. Transparent tunnelling over a microwave hop. The tunnels are fully transparent to any frames and are invisible to each other. If it is desired to keep the assigned outer tag at the other end and aggregate traffic to a single port, then the port type is set to trunk and assigning all VIDs to the same port. Figure 66 below. Figure 66. Traffic aggregation. Customer tunnels terminated in a single Trunk port Again, in this case the customer VIDs may be unknown, but the outer tags need to be coordinated on the core network side and processed somewhere else in the network. 75 Figure 67. Settings for Figure 66 trunk Ethernet port. All three VLANs are assigned to the same trunk port (MC-A4 Port 02). FDB Setting Forwarding Data Base contains the L2 switch MAC-address settings. Retrieve Current FDB – check and store the MAC-addresses e.g. for trouble shooting. Use a Microsoft application to open the file (e.g. Word, WordPad or Excel) to see the file in a readable format. Ethernet OAM Setting This is a complex collection of settings not explained in this document version. RSTP Setting In simple networks consisting of linear and branching point to point links this setting is not required. STP Mode = Disable. Link Aggregation Setting Normally there are no LAG groups unless the Ethernet connection from the IDU to an external switch needs to be redundant (use dual cables and interfaces) or unless single cable capacity is not sufficient (e.g. 2 x FE ports only available in the external switch). The LAG group will balance the traffic (with limitations) between the two ports. ERP Setting Ethernet Ring Protection is not addressed by this document version. 76 QOS SETTINGS Provisioning - > Ethernet Function Setting -> QoS/Classification Setting Each port of the iPasolink L2 switch can be configured for certain QoS settings. The next section describes the principles of iPasolink QoS operation in general. TRAFFIC CLASSIFICATION PRINCIPLES The functional QoS block diagram of the IDU is presented in Figure 68 below. Table 15 contains a summary of the functions and associated settings. Figure 68. QoS block diagram. The superscripts refer to the text. 77 Block Function Setting IC (Internal Classifier) Classify (map) the ingress frame to internal priority Classify Entry Profile (1) Description Notes Assign internal priority based on CoS (p-bit) or IP v4/v6 DSCP or MPLS Exp value. Equipment Based Mode: one user defined mapping profile common to all ports based on CoS p-bit. If p-bit is missing, can define internal priority based on ipv4 Prec, ipv4/v6 DSCP or MPLS Exp or use a default internal priority. Always adds a VLAN tag. Select Profile No. VLAN tag CoS value copied from incoming frame or if tag missing use L3 priority value. PO (Policer) (2) EC (Egress Classifier) Colour marking based on the outer tag CoS-value. Port Based Mode: each port may use one of the following a) CoS-based default mapping (1-1, 2-2 etc), b) user defined DSCP-classification or c) port default priority. Ingress Setting ”2-rate 3-colour”. Ingress Policer Profile Setting CIR, EIR, CBS, EBS When a high packet rate burst is too long, it is marked Yellow or Red (dropped). Normally packet is Green. Setting per port and per VLAN Red limit is approximately CIR + EIR for a continuous stream. Internal priority and the physical ingress port define the Queue Class. Egress port does not have any effect in the egress queue classification. Classify frame to an Egress Queue Class based on the internal priority and the physical ingress port. QoS Port Setting List/Internal Priority Queuing Policy per Ingress SW (Switch) L2 internal switching VLAN Setting L2 switch directs the frame to the egress port based on the VLAN settings and frame outer VID. Egress port may be Ethernet port or one of the modem ports EQS (Egress Queue/Shaper) Egress port queuing, queue class based shaping and port based shaping QoS Port Setting List/Port Setting Dropping yellow and even green frames when the queue is too long. Queue management Strict priority class bypasses the queuing. Dual shaping per class and per egress port. (3) (4) Table 15. QoS summary Number of classes 4 or 8. Note: the default mapping profile (one to one) plus two user defined mapping profiles may be used. Egress Class Setting Information 78 The Qos processing of frames consists of four phases from ingress port (e.g. Ethernet port) to egress port (e.g. modem port). The process is similar in the reverse direction but the QoS settings may be totally different (Figure 68). 1) Incoming or ingress frames are classified into an internal priority value (”IC” in Figure 68) based on customer VLAN-tag L2 priority (p-bit) value or customer L3 priority value (IPv4 tai IPv6 DSCP) or MPLS Exp –priority value. The classification is to internal priority. In this phase, if a VLAN tag is added, the CoS value is copied or if missing, the CoS value is based on the internal priority classification. In the Port Based QoS –mode the VLAN-tag priority is copied as such from the internal priority. In this mode VLAN-frames can be classified internally based on IP v4 or IP v6 DSCP-priority using the default mapping: VLAN CoS value is not used but the DSCP value. The outer tag CoS value is always copied from the inner tag, however. (This will change in a later version). If the ingress frame has no tag, the CoS value is the internal priority. In the Equipment Based QoS mode the VLAN tag p-bit will always decide the internal priority over any L3 priority and it can be mapped as wanted to the internal priority (single profile for all ports). If the frame has no VLAN tag, it is possible to select IP v4 Precedence, IP v4 DCSP, IP v6 DSCP tai MPLS Exp –value based internal priority which is also the VLAN tag CoS value. In this mode the classification is common to all ports of the IDU. The third available mode is VLAN ID Based QoS Mode. Internal priority is based on the VID only, nothing else. Note that the ingress frame priority classification into internal priority is also applicable to the modem port. 2) In the second phase, the frame is Ingress Policer classified based on outer tag CoS value (original or added tag). ”PO” in Figure 68. Ingress Setting tab (Figure 69). Total 16 Policer profiles can be added. Define CIR (Committed Information Rate), EIR (Excessive Information Rate, i.e. tolerance above CIR) as well as EBS (Excessive Burst Size, EBS kbyte) and CBS (Committed Burst Size, CBS kbyte). The burst sizes and the rates define when the frame is marked Yellow or Red (and dropped immediately). Note. RFC4115 implementation in iPasolink is such that PIR (Peak Information Rate) = CIR+EIR is the limit when the frames are marked Red based on the EBS setting. As an example CIR = 100 Mbit/s and EIR = 50 Mbit/s will transmit almost 150 Mbit/s continuously. 79 3) In the third phase each internal priority is mapped in on of 4 or 8 Egress Queue Classes. The setting is per ingress port but the different mappings is limited to three (one default one-to-one and two user configurable). ”EC” in Figure 68. 4) Based on the ingress port settings the frame (Green, Yellow or Red) will be switched to the egress port based on the VLAN assignments. At the egress port it will go to the queue (or bypass the use if the class is Strict Priority) as defined in the previous phase. For each class there is a Shaper Rate, Weighting Factor and Queuing method as well as threshold values for the Queue length for dropping first Yellow and then Green frames. The egress port also has a Shaper Rate that cannot be exceeded (in the modem port it depends on the channel spacing and modulation and E1 channels in use, in other ports it can be set manually). “EQS” in Figure 68). The scheduling mechanism is Deficit Weighted Round Robin (DWRR) and the drop mode is either WTD (Weighted Tail Drop) or WRED (Weighted Random Early Discard). QoS planning depends on the operator requirements and the settings should be modified for each case. SAMPLE QOS POLICY In this example ”802.1Q User Priority” is used, with four priority classes: Class 0 (BE, Best Effort), Class 1 (BE+, Best Effort+), Class 2 (BC, Business Critical), Class 3 (RT, Real Time) and Class 4 (NC, Network Critical); classes 5 and 6 are not used. The highest class (7) is given Strict Priority, SP and the other 5 classes use Weighted Random Early Discard, WRED. The class weights are from low to high 1:5:29:89:3:1:1. In this example the ”Port Based QoS Mode” with incoming frame CoS(C-Tag) classification. Figure 69. There is no Ingress Policer defined, in other words all ports may use as much bandwidth they want for any priority (it is assumed that policing is handled by external equipment). Setting Default Port Priority = 0 means that any untagged frames will be given internal priority = 0, provided that VLAN settings allow any untagged frames. Ingress 802.1q frame p-bit Class Egress Queuing Class mapping, EC Weight, WRED BE Assigned internal priority, IC 0 0 (000) or missing tag 1 (001) 2 (010) 3 (011) 4 (100) 5 (101) 6 (110) 7 (111) 0 1 BE+ BC BC RT RT NC “7” 1 2 3 4 5 6 7 1 2 2 3 3 4 7 5 29 89 3 (SP) Table 16. CoS-classification into egress queues. There will be nothing in the egress port queue class 5 or 6. 80 QOS SETTINGS – CLASSIFY AND INGRESS POLICING Figure 69. Classification Mode: port based QoS and CoS(C-tag)-mode. Select Port Based QoS Mode. Select CoS (C-Tag) Port Classification Mode for all ports. Figure 69. Default Port Priority = 0 for untagged frames. Ingress Policer –settings are left empty. All frames are then treated equally. The ingress port, VLAN or bandwidth usage of the port will not affect the egress queuing. Figures 70-71. Figure 70. Ingress Setting is empty in the example. 81 Figure 71. Add Policer Index: here Policer Profile would be selected if necessary. Under Provisioning -> ETH Function Setting -> QoS / Classification Setting -> Port Setting the Class Mode is selected, following the example 8 classes. Figure 72. This setting is common for all ports including the modem. Figure 72. Class Mode Setting (number of egress queues in each port). 82 PORT QOS SETTINGS The settings for the QoS policy example are described here. Table 16 shows one-to-one mapping from CoS to internal priority which is the default setting in the Port Based QoS Mode and cannot be changed in this mode. The settings for each ingress port have to be modified: mapping from internal priority to egress queue class, scheduling, shaping and WRED-settings. Figure 73. QoS Port Setting List. The egress port queuing class for each ingress frame is set based on the ingress port and the internal priority in tab Port Setting. The summary page right side Class Info /Detail link opens the Egress Class Detail settings for that port (Figure 74). Further, the Class number link opens the Egress Class Setting (Figure 75). The Port-link on the summary page (Fig. 73) opens the port settings (Figure 76). Figure 74. Summary of the port Egress settings. Edit each class settings using the link. 83 Shaper Rate = 1000M in all classes (= no speed limit). DWRR (Deficit Weighted Round Robin) Weight defines the capacity usage between the classes (excluding SP class). The sum of the weights is 1+5+28+89+3 = 127, therefore Class 0 gets 1/127 = 0,79% of the capacity left after SP-class frames are transmitted, in the case when there is congestion. Queue Length defines burst handling and on the other hand latency and jitter. The Yellow Frame Threshold –settings are meaningless if no colouring is used. Green frames are being dropped in the WRED mode when the queue is 70 per cent full. Figure 75. Class 2 settings for one Ethernet port. Note. FW 3.00: queue length is 1024 kbyte (was 128 kbyte). MC-A4 Port01 QoS mapping (in Figure 76) determines the modem queue of the incoming frame. The modem port QoS mapping setting will decide the egress queue at the egress Ethernet port. Figure 76. Port QoS settings based on the sample QoS policy. 84 In the top part of Figure 76 Port Setting are the egress queue settings for this port. This setting affects the frames going out of the equipment. In the middle in Figure 76 (with the complex heading) are the settings affecting the incoming (ingress) frames to this port, i.e. opposite direction from the setting above. Lower part in Figure 76 (Egress Class Setting Information) describes again queue settings affecting egress frames queuing out of the equipment to this Ethernet port. In most cases the bottle-neck is the modem. In that case only the middle part of the Ethernet QoS port setting (the ingress frame mapping) has any real effect. Correspondingly the modem queue settings are crucial. QOS SETTINGS SUMMARY After repeating the settings for all ports the Port Setting summary looks as Figure 77. Figure 77. Summary of QoS settings. In this case the mapping is identical and all the QoS settings for all ports are identical except for the modem Egress Shaper rate which depends on the Channel Spacing and current Modulation. 85 COPYING SETTINGS FROM ONE IDU TO ANOTHER Manual setup of the IDU is quite complicated and prone to errors. It is easier to copy most of the settings from a reference IDU to a USB-stick in the IDU port or to PC hard disk or USB or to the NMS server. The settings can then be restored to another IDU either fully or partially. The remaining settings (element settings, such as channel frequencies) would then be edited manually. The restore operation is possible without a PC from a USB-memory stick locally. It can also be done using a PC either locally or remotely. COPYING SETTINGS TO USB WITHOUT PC Note. The USB memory has to be clean or at least is must not contain a config-folder with the .cfg files. The settings can be copied once, then the config-folder has to be deleted, emptied or renamed using a PC. Insert a USB stick in to the IDU (power on). Copying starts when the front PROTECT-switch is turned UP. Wait for about 30 seconds. Turn the switch back DOWN (normal position). Wait until MAINT led stops flashing. The USB stick should now contain folder “config” with three CFG-files. Figure 78. Configuration files. ”iPasolink-equip” contains settings under the Equipment Configuration, Radio Configuration, AMR /Radio Mapping Configuration and Provisioning tabs. Binary file. ”iPasolink-network” contains settings under the Network Management Configuration tab. Text file (do not edit). ”iPasolink-user” contains settings under the User Account/Security Setting tab settings. Binary file. RESTORING SETTINGS WITHOUT A PC The settings can be restored from the USB stick to the same or another IDU without a PC. The limitation is that the source and target IDU have to have the same HW configuration: same plug-in units/cards installed. More precisely: the target IDU has to have the same units inserted in the IDU which were “Used” in the source IDU. The restore fails if there is something more or something less inserted in the target IDU than was in use in the source IDU. This method makes a full restore, i.e. copies all three files. However, it is possible to delete one or two files in the config-folder and restore the settings contained in that file only. The file name must not be modified. 86 Turn off the target IDU. Wait for at least 10 seconds. Insert the USB stick with config folder and the CFGfiles into the USB port of the IDU. Turn the PROTECT switch UP. Now reconnect DC-power to the IDU. Wait for about 2 minutes until the MAINT led stops flashing but remains ON. Now turn the PROTECT switch back DOWN (normal position). After one minute the MAINT led will start flashing again (rebooting). Wait one more minute until the MAINT led stops flashing and remains OFF. Remove the USB stick now. The IDU should now operate using the settings copied from the USB folder. COPYING SETTINGS USING THE BROWSER Equipment Utility -> Export (NE -> Storage) Utility Figure 79. Copying (export) settings to the local PC Select e.g. Equipment Config Data and press Execute. Browser window opens, select Save File and select a suitable folder and save the file. If the IDU USB port has a USB stick inserted, it is possible to select Export to USB Memory. Press Execute and wait for window “Complete” and press OK. 87 The USB Memory Utility can be used to check the contents of the USB stick in the USB port. It will list the Export-files. The files are actually in the USB memory folders ”config” and ”inventory”. USB Memory Utility does not show any other folders. In this method the system will overwrite existing files in the config-folder without any warning. Please rename the file or folder if the file must not be overwritten. RESTORING SETTINGS USING THE BROWSER Under Update (Storage->NE) the files can be copied to the IDU either from PC disk or USB memory. The following shows the use of USB stick inserted into the USB port. With a PC the operation is similar and the file management is easier because any folder can be used. Figure 80. Restoring (update) the settings to the IDU. Select Config Data and press Execute. Warning appears that Maintenance mode is required. (Figure 81 below). Figure 81. Press OK to switch maintenance mode on. Press OK and then Execute again. 88 Figure 82. Partial Restore. The window (Figure 82) allows selection of e.g. Partial Equipment Config and Import File/USB Memory, further click the folder symbol to the right of USB Memory line. A new window opens. (Figure 83). Select in the USB stick the config/iPASOLINK-equip.cfg file and click OK. Note that the system does not see any other folders than the config and inventory folders. In this method the file name does not matter as far it is xxx.cfg and contains the correct data. Figure 83. File selection. Select the proper file and OK. Continue Next> (Figure 84). 89 Figure 84. Partial Restore continues. Next window (Figure 85): select e.g. ETH Function Setting (or whatever settings need to be restored). Note. The remote management may become impossible if the relevant settings are changed. Figure 85. Select settings to copy to the IDU. Accept the warning, OK (Figure 86). Figure 86. Warning accepted: OK. Close the browser window and wait for the IDU to reset. Note that traffic will be interrupted. Typically it takes 2-3 minutes to reset including a traffic interruption of 1 to 2 minutes. Locally the MAINT led stops 90 flashing and remains OFF when the IDU has rebooted. The traffic should return to normal very soon thereafter. In some cases the PC LAN card has to be reset (disable/enable) after the IDU reset in order to reconnect to the LCT port. Do not pull the DC power while the IDU is resetting (MAINT led flashing). Note. Ethernet settings restore (Partial Equipment Config) has the limitation that the source and target IDUs have to be identically equipped. See also “Restoring Settings without a PC”. PRECONFIGURATION FILES Appendix D is a Quick Guide: how to install a new IDU when the common default settings have been prepared in a reference IDU in advance. Most of the settings are copied to the new IDU using configuration files. If the IDU will use more cards than the reference IDU, these cards have to be physically removed before copying the CFG-files to the IDU. The additional cards should then be reinserted and their settings done manually as described in Appendix D and the rest of this document. 91 KNOWN PROBLEMS CANNOT CONNECT THE BROWSER TO THE LCT PORT Check that the PC LAN card is enabled and that the settings are correct (automatic IP address using DHCP). Check that the PC LAN card has the IP address in the same subnet as the LCT port (172.17.254.xxx). Check that the LCT-port IP-address in the browser is the same as the PC LAN card ”default gateway” which is always 172.17.254.253. Try removing the PC LAN card physically or disable/enable it using the Control Panel. Check that pop ups are allowed in the browser. Lower security settings in the browser: Security Settings = Low. Disable the PC firewall – this should never be a problem, however. Remove and reinstall the PC LAN card driver – this will return the card to default settings. CANNOT ACCESS REMOTE IDU OR ”COMMUNICATION ERROR” If the pull down menu for the opposite IDU is empty, refresh the browser window (F5) Check that the hop is OK (RX levels OK and BER = 0) Verify Synchronization Settings: Master/Internal and opposite end is Slave/Modem. Check that the Slave is configured to sync to the correct Master side modem, if more than one modem is in use. Check the Bridge mode: identical in all IDUs in the cluster (e.g. 802.1q) Verify that the modem is connected to Bridge1 port (in the NMS settings). 92 APPENDIX A. RECEIVER THRESHOLD DATA Frequency Band (GHz) 6G 7-8 1011 13 15 23 26 28 32 38 42 -84.5 -84.5 -84 -83.5 -83.5 -83 -83.5 -82.5 -82.5 -82.5 -81.5 -79.5 16QAM -78 -78 77.5 -77 -77 76.5 -77 -76 -76 -76 -75 -73 32QAM -75 -75 74.5 -74 -74 73.5 -74 -73 -73 -73 -72 -70 64QAM -72 -72 71.5 -71 -71 70.5 -71 -70 -70 -70 -69 -67 128QAM -69 -69 68.5 -68 -68 67.5 -68 -67 -67 -67 -66 -64 256QAM -65.5 -65.5 -65 -64.5 -64.5 BER = 10-3 -64 + 3.0 dB -64.5 -63.5 -63.5 -63.5 -62.5 -60.5 Above value -1.0dB (dB measured at Ant. port) BER = 10-6 System Gain QPSK 113.5 113.5 109 108.5 108.5 107 107.5 105.5 104.5 104.5 101.5 99.5 16QAM 104 104 99.5 99 99 97.5 98 95 94 94 92 89 32QAM 100 100 95.5 95 95 93.5 92 91 91 91 89 86 64QAM 97 97 92.5 92 92 90.5 89 88 88 88 86 82 128QAM 94 94 89.5 89 89 87.5 86 85 85 85 83 79 256QAM 89.5 89.5 85 84.5 84.5 83 81.5 80.5 80.5 80.5 78.5 74.5 BER = 10-3 Table A-1. 56 MHz Guaranteed (dBm measured at Ant. port) BER = 10-6 Threshold Level QPSK 18 Above value +1.0dB 6-28G: - 3.0 dB 32-42G: - 4.0 dB 93 Frequency Band (GHz) 6 7-8 1011 13 15 Threshold Level QPSK 18 23 26 28 32 38 42 Guaranteed (dBm measured at Ant. port) BER = 10-6 -87.5 -87.5 -87 -86.5 -86.5 -86 -86.5 -85.5 -85.5 -85.5 -84.5 -82.5 16QAM -81 -81 -80.5 -80 -80 -79.5 -80 -79 -79 -79 -78 -76 32QAM -78 -78 -77.5 -77 -77 -76.5 -77 -76 -76 -76 -75 -73 64QAM -75 -75 -74.5 -74 -74 -73.5 -74 -73 -73 -73 -72 -70 128QAM -72 -72 -71.5 -71 -71 -70.5 -71 -70 -70 -70 -69 -67 + 3.0 dB 256QAM -68.5 -68.5 -68 -67.5 -67.5 BER = 10-3 -67 Above value -1.0dB System Gain QPSK -67.5 -66.5 -66.5 -66.5 -65.5 -63.5 (dB measured at Ant. port) BER = 10-6 116.5 116.5 112 111.5 111.5 110 110.5 108.5 107.5 107.5 104.5 102.5 16QAM 108 108 103.5 103 103 101.5 102 99 98 98 96 93 32QAM 104 104 99.5 99 99 97.5 96 95 95 95 93 89 64QAM 101 101 96.5 96 96 94.5 93 92 92 92 90 86 128QAM 98 98 93.5 93 93 91.5 90 89 89 89 87 83 256QAM 93.5 93.5 89 88.5 88.5 87 85.5 84.5 84.5 84.5 82.5 78.5 BER = 10-3 Table A-2. 28 MHz Above value +1.0dB 6-28G: - 3.0 dB 32-42G: - 4.0 dB 94 Frequency Band (GHz) 6 7-8 1011 13 15 Threshold Level QPSK 18 23 26 28 32 38 42 Guaranteed (dBm measured at Ant. port) BER = 10-6 -90.5 -90.5 -90 -89.5 -89.5 -89 -89.5 -88.5 -88.5 -88.5 -87.5 -85.5 16QAM -84 -84 -83.5 -83 -83 -82.5 -83 -82 -82 -82 -81 -79 32QAM -81 -81 -80.5 -80 -80 -79.5 -80 -79 -79 -79 -78 -76 64QAM -78 -78 -77.5 -77 -77 -76.5 -77 -76 -76 -76 -75 -73 128QAM -75 -75 -74.5 -74 -74 -73.5 -74 -73 -73 -73 -72 -70 256QAM -71 -71 -70.5 -70 -70 -69.5 -70 -69 -69 -69 -68 - + 3.0 dB BER = 10-3 Above value -1.0dB System Gain QPSK (dB measured at Ant. port) BER = 10-6 119.5 119.5 115 114.5 114.5 113 113.5 111.5 110.5 110.5 107.5 105.5 16QAM 111 111 106.5 106 106 104.5 105 102 101 101 99 96 32QAM 107 107 102.5 102 102 100.5 99 98 98 98 96 92 64QAM 104 104 99.5 99 99 97.5 96 95 95 95 93 89 128QAM 101 101 96.5 96 96 94.5 93 92 92 92 90 86 256QAM 96 96 91.5 91 91 89.5 88 87 87 87 85 - BER = 10-3 Table A-3. 14 MHz Above value +1.0dB 6-28G: - 3.0 dB 32-42G: - 4.0 dB 95 APPENDIX B. MC-A4/16E1-A MDR68-CONNECTOR PIN LAYOUT PIN E1 channel 2 PIN E1 channel 11 Ch 16 in PIN E1 channel 20 Ch 12 out PIN 29 Ch 7 in Ch 3 out 36 45 54 63 3 12 21 30 Ch 16 out Ch 11 in Ch 7 out Ch 2 in 37 46 55 64 4 13 22 31 Ch 15 in Ch 11 out Ch 6 in Ch 2 out 38 47 56 65 5 14 23 32 Ch 15 out 39 Ch 10 in 48 6 40 41 50 59 8 17 26 Ch 9 out 42 51 60 9 18 27 Ch 13 out Ch 8 in 43 52 61 10 19 28 Ch 12 in 44 Ch 8 out 53 ch 1 out 67 25 Ch 9 in Ch 13 in 33 Ch 5 in 58 16 Ch 14 out Ch 1 in 66 24 Ch 10 out 49 7 Ch 6 out 57 15 Ch 14 in E1 channel 62 Ch 5 out 1 GND Ch 4 in 35 GND Ch 4 out 34 GND Ch 3 in 68 GND 96 APPENDIX C. MC-A4 D-SUB-44 CONNECTOR PIN LAYOUT Figure C-1. MC-A4 –card (ALM/SC/CLK) connector pin layout. V11 IDT is the input data and ODT is the output data. For synchronous V.11: ICK is the clock input and OCK is the clock output. IFP and OFP are the input and output for the frame timing, respectively. 97 APPENDIX D. QUICK INSTALLATION GUIDE/CHECK LIST One IDU has to be configured manually for the root-element settings most commonly used. The setting files should be copied and used during IDU installations. 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. Copy the three default setting files for a default root-element to a USB stick’s config-folder Turn off the new IDU to be installed Remove all units not belonging to the default configuration Copy the settings from the USB stich to the IDU Turn off the target IDU Wait for at least 10 seconds Insert the USB stick with config folder and the CFG-files into the USB port of the IDU Turn the PROTECT switch UP Now reconnect DC-power to the IDU Wait about two minutes until the MAINT led stops flashing but remains ON Now turn the PROTECT switch back DOWN (normal position) After one minute the MAINT led will start flashing again (it is now rebooting) Wait one more minute until the MAINT led stops flashing and remains OFF Remove the USB stick now Insert any additional cards now. Connect a PC to the LCT-port: 172.17.254.253/Admin/12345678 and do the element settings: Equipment Setup -> Equipment Configuration -> Setup-button NE name (NE Name, page ) Select modules in use (Used/Not Used , Auto detect) 1+1 setting or XPIC setting as required Equipment Setup -> Radio Configuration -> Setup, New Setting Channel Spacing Reference Modulation TX Frequency, MHz, page 48), verify RX Frequency from the license data Radio Traffic Aggregation settings for XPIC Network Management Setting -> General Setting (Detail), Setup Provisioning –> Modem Function Setting Modem Port Setting, modem name TX Power Setting: MTPC TX power (dBm), maximum power Provisioning -> Equipment Clock / Synchronization Setting Root=Master, other end = Slave Equipment Utility -> Date / Time Setting -> Modify Copy PC time, Display PC Time User Account /Security Setting -> Security Management -> Service Status Setting NTP Server IP address for the root element NTP Server = root Bridge1 address Antenna alignment verify that AMR is not in use, set QPSK, MTPC and maximum power align the antennas verify that the hop attenuation is correct 98 15. Equipment Setup -> AMR / Radio Mapping Configuration -> Setup, New Setting AMR Operation enabled = ”AMR Mode” Select modulation levels QSPK, 16QAM Set the number of E1/STM-1 channels for each modulation level 16. Provisioning –> Modem Function Setting TX Power Setting: set the MTPC TX power (dBm) as given in the license 17. Provisioning -> E1/STM-1/Cross Connect Setting enable the required E1-ports cross-connect the E1 channels 18. Check the NMS connection ping from the LCT port the NMS server IP address request pinging test from the NMS server to the NMS port and Bridge1 addresses request connection to be made to the NMS 19. Provisioning -> ETH Function Setting enable Ethernet ports make VLAN settings make QoS setting 20. Reset PMON counters and the event logs. Maintenance Control/PMON/RMON FDB Clear Equipment Utility/Log Clear Function. Author: Pekka Linna, NEC Finland Oy, +358 400 604747. email: pekka.linna@emea.nec.com