4Motion® System Manual Release Version: 3.
Document History Document History Topic Description Date Issued First Release for GA July 2008 Rate limits are configurable only by the vendor. May 2009 Section 3.4.7.2 Configuring ACLs Updated default ACLs. May 2009 Added support for new counters groups, updated names. May 2009 Updated Defaults for cqi, cdma, qam64-1by2, qam64-2by3, qam64-3by4, qam64-5by6. May 2009 Updated commands’ syntax.
Document History Topic Description Date Issued Airframe Mapping Parameters Previously Section 4.8.16.2.6 Updated descriptions. May 2009 Airframe Receive Parameters Previously Section 4.8.16.2.7 Updated descriptions. May 2009 Airframe Downlink Diversity Parameters Changed value range and default for the MIMO parameter. May 2009 Airframe MIMO Parameters Sections 3.9.12.2.7, 3.9.12.3.4, 3.9.12.5.7 New Airframe parameters table. May 2009 Neighbor BS General Parameters Sections 3.9.9.2.1, 3.9.9.
Document History Topic Description Date Issued Handover Negotiation at SBS (was previously 4.8.12) All Handover Negotiation at SBS parameters were removed. May 2009 UCD Parameters (was previously 4.8.15) All UCD parameters were removed. May 2009 DCD Parameters (was previously 4.8.16) All DCD parameters were removed. May 2009 Authentication Relay Parameters Removed: nonauth-macctrlratethrshld, nonauth-pduratethrshld May 2009 Section 3.9.
Document History Topic Description Date Issued AU Connectivity Parameters Sections 3.6.2.3, 3.6.3.3, Added new parameters: service-ip, service-mask, service-next-hop. May 2009 3.6.6.3 Configuring Physical and IP Interfaces Updated possible values of bearervlanid and the read-only InternalManagementVLANID parameters. AU Fast Ethernet interfaces are not configurable. May 2009 Updated with new parameters/commands and additional changes related to support of multiple AAA clients and AAA Redundancy.
Document History Topic Description Date Issued Service Profile profile-name possible values changed to 1-30 characters, May 2009 clsf-rule possible values changed to 1-30 characters, May 2009 phs-rule possible values changed to 1-30 characters, May 2009 qos-alias possible values changed to 1-30 characters, May 2009 Section 3.4.12.11.3.1 Classification Rules Section 3.4.12.11.4.1 PHS Rules Section 3.4.12.12.1 Bearer Plane QoS Marking Rules Section 3.4.12.7.
Document History Topic Description Date Issued AU Properties Sections 3.6.2.1, 3.6.3.1, Updated possible values for required-type. May 2009 3.6.6.1 Removed: required-ports, required-bandwidth (and the corresponding InstalledPorts and InstalledBandwidth). Updated options for port-3 power and port-4-power parameters (removed the NA option). Sector Parameters Section 3.10.1 Antennas Section 3.8 heading is not mandatory when creating a new sector. The default value is 0.
Document History Topic Description Date Issued MS State Change Parameters Configurable only by the vendor. Updated display format. May 2009 Section 3.4.12.5 Connectivity Service Network (CSN) Parameters Configurable only by the vendor. Updated display format. May 2009 Added default (disable). May 2009 Removed: ulSfQosSduSize, dlSfQosSduSize. May 2009 Section 3.4.12.6 Enabling/Disabling VLAN Service Interface Section 3.4.12.10.3 Service Flows Sections 3.4.12.11.3.3, 3.4.12.11.3.
Document History Topic Description Date Issued ODUs Sections 1.3.4, 2.1.3, 3.7.1.1, 3.7.1.2, 3.7.1.6, 3.7.2. Tables 1-3, 1-6, 1-10, 1-22. Added new ODUs: ODU-HP-2.3-WCS, ODU-2340-2400-000N-36-1X1-N-0, ODU-2480-2690-000N-38-4X2-N-0. May 2009 Removed: 2x1 ODUs. Updated the list of ODU types in CLI (including types that are not available yet). ODU General Parameters Sections 3.7.1.2, 3.7.1.3, 3.7.1.6. Removed: heater-existence May 2009 Antennas Added antennas: May 2009 Table 1-39, Table 1-42 ANT.
Document History Topic Description Date Issued VLAN Service Interface Parameters Sections 3.4.12.8.2.2, Updated syntax of commands for better support of commands auto-completion. May 2009 Updated possible values and description for vlan-id. Added mask for dflt-gw-ip. QinQ Service Interface Parameters Section 3.4.12.8.2.3 Updated syntax of commands for better support of commands auto-completion. May 2009 Updated possible values and description for vlan-id.
Document History Topic Description Date Issued Power Feeders Requirements Section 2.3.3.3 Required only in configurations with 6 AUs where each AU is connected to 4 2.x GHz or 3.5 GHz 1x1 ODUs. May 2009 Configuring the Properties of the Physical Interface Physical interfaces can be configured when the interface is enabled. May 2009 Up to 6 AUs may be active (removed limitation on number of AUs that can provide services).
Document History Topic Description Date Issued Creating a Sector Association Entry Updated association rules (relation between antenna-type, auto-diversity and auto-rx-enable parameters. May 2009 Reset is required only for a change in Connectivity Mode. June 2009 Section 2.1.3.4 Accessing the CLI from a Remote Terminal No need to disable/enable the interface when configuring an IP Address. June 2009 Updated the command’s syntax. June 2009 Updated display format. June 2009 Updated ranges.
Document History Topic Description Date Issued Managing the Authenticator Function Updated descriptions for eapTimerTransfer and eapCounterTransferMax. June 2009 Updated descriptions of dpTimerInitPathRegReq, dpCounterInitPathRegReqMax, dpTimerMsDeregReq, dpCounterMsDeregReqMax, dpTimerPathRegReq, dpCounterPathRegReqMax, dpTimerPathRegRsp, dpCounterPathRegRspMax. June 2009 Updated descriptions of all parameters.
Document History Topic Description Date Issued Configuring the AAA Client Functionality rad-CallingStationId parameter added to AAA Client parameters config command (instead of config aaaserverMACFormat command added in a previous version of this release). June 2009 Updated command syntax and description. June 2009 “default” client cannot be deleted. June 2009 No need to delete service group for updating pool-minaddr & pool-maxaddr values. June 2009 Section 3.4.12.
Document History Topic Description Date Issued Configuring the Date and Time Corrected the presence of UTC to Optional. June 2009 Added note on error condition. June 2009 Corrected command’s syntax. June 2009 Updated description. June 2009 Displaying Location Information for the 4Motion Shelf This section (previously Section 4.10.1.4) was removed (described in Section 3.4.16.7.2). June 2009 Displaying the Unique Identifier for the 4Motion Shelf This section (previously Section 4.10.1.
Document History Topic Description Date Issued Enabling the Source Address Configuration Mode\ Creating a New Source Address Added Privilege Level definition. June 2009 Updated Privilege Level (10) June 2009 Added to manual. June 2009 Updated Privilege Level (10) June 2009 Updated Privilege Level (10) June 2009 Updated Privilege Level (10) June 2009 Updated Privilege Level (10) June 2009 Displaying Status Information for HARQ Maximum Retransmissions Parameter (was previously section 4.8.
Document History Topic Description Date Issued Enabling Protocol Lists Added consistency rules-impact of enabling destination port range June 2009 Added consistency rules-impact on parameters of IP protocol lists June 2009 Added consistency rules-impact on parameters of IP protocol lists June 2009 Section 3.4.12.11.4.7.2 Configuring the Position Updated ranges for longitude and latitude.
Document History Topic Description Date Issued Macro Outdoor BTS Sections 1.2.1, 1.3, 1.3.2 (new), 1.5.6, 1.5.7, 1.5.9, 1.5.10.2.1 (new), 1.5.10.2.2 (new), 1.5.10.2.3 (new), 2.4 (new). 3.1.1 (new) New product line June 2009 Configuring the Site General Information for the 4Motion Shelf Removed ProductType (not configurable) June 2009 Product Type has several options. June 2009 Replacing a PIU Section 2.3.10.4 Updated procedure June 2009 Output Alarms Corrected explanation of N.C. and N.O.
Document History Topic Description Date Issued Specifying Service Flow Configuration Parameters Updated value range for ulqos-maxsustainedrate, dlqos-maxsustainedrate, ul-rsrv-rate-min, dl-rsrv-rate-min. August 2009 Updated default value of bcast-msgzone-loc. August 2009 Managing the Policy Framework (was previously section 4.3.11.17) Removed August 2009 Managing Handover Negotiation at SBS (was previously 4.8.
Document History Topic Description Date Issued Configuring Airframe Receive Parameters Previously Section 4.8.16.2.7 The values are set by internal logic. August 2009 Configuring Antenna Parameters Updated possible values and default for antenna-product-id. August 2009 Section 3.8.2 Configuring Airframe Uplink Feedback Zone Parameters Value of subchannels is set internally according to bandwidth. August 2009 Value of subchannels is set internally according to bandwidth.
Document History Topic Description Date Issued Configuring the Unique Identifier for the 4Motion Shelf A change in site identifier will take effect after reset. August 2009 Section 3.4.16.8.1 Managing the IP Connectivity Mode Section 3.4.1 Configuring Physical and IP Interfaces Special procedure needed when changing the site identifier of a device managed by AlvariSTAR. Added AU maintenance IP domain. August 2009 Added note on VLAN operation mode of the ports (tagged/untagged).
Document History Topic Description Date Issued 1x1 ODU LEDs Table 2-3 ETH connector is functional August 2009 Configuring General Neighbor BS Parameters Updated range for frequency August 2009 Updated range for frequency August 2009 Updated range for srvcflow-datadeliverytype. August 2009 Added note that after changing the bearer interface VLAN ID the bearervlanid of all AUs must be changed to the same value. August 2009 Added note-reset required. August 2009 Added note-reset required.
Document History Topic Description Date Issued Configuring Airftame Parameters Removed sections related to Cyclic Delay Parameters, Linear Delay Parameters, Mapping Parameters and Receive Parameters. In General Parameters, auto-diversity and auto-rx-enable were removed. August 2009 Section 3.9.12.2 Added notes regarding parameters that are not relevant (ignored) in Uplink Feedback Zone Parameters, Downlink Data Zone Parameters, Uplink Data Zone Parameters, MIMO Parameters.
Document History Topic Description Date Issued Managing Power Control Levels Removed sections related to configuring or restoring the default value of Maximum EIRxP. Added a note that this command is not applicable for the current release. Updated the description for displaying configuration values of the parameter. August 2009 Section 3.9.4 Added a note regarding nilevels cqi-ack-ranging parameter that cannot be modified. Required C/N Levels are configurable.
Document History Topic Description Date Issued Configuring the 4Motion Shelf Updated descriptions of components. September 2009 Updated general description September 2009 Updated range for pusc. September 2009 Updated-added the options to de-rergister am MS by its MSID (MAC address) and de-register all MSs served by a specified BS. October 2009 New feature October 2009 New feature October 2009 Added the command “show saved system logs”. October 2009 Section 3.11.
Document History Topic Description Date Issued Adding a Static Route Updated: ip_nexthop must be in the subnet of one of the NPU IP interfaces. October 2009 New command October 2009 .Added: If no classifier is associated with the service flow for one or both directions, it means any traffic. October 2009 Updated description October 2009 Updated description-priorities of ACLs October 2009 Removed alrmAaaSwitchoverRetryFailThrshld. November 2009 Section 3.4.9.
Document History Topic Description Date Issued ODU Types Added new ODUs: February 2010 Table 1-3, Section 1.5.3 ODU-2300-2400-000N-38-2X2-N-0 ODU-2485-2690-000N-38-2X2-N-0 ODU-2590-2690-000N-38-2x2-N-0 ODU-3345-3400-000N-33-1x1-N-0 ODU-3400-3600-000N-37-2x2-N-0 ODU-3400-3600-000N-37-4x2-BF-N-0 ODU-3650-3700-000N-22-1x1-N-0 Added Beam Forming Support specifications to all 4x2 ODUs tables. Added ETSI compliance requirements for 2.5 GHz ODUs.
Document History Topic Description Date Issued Airframe Dynamic Permutations Parameters Removed (changed to vendor parameters) February 2010 Updated value range for ul-duration and frame-offset. Added nbr-beam-forming. February 2010 Added RCID-Usage February 2010 Removed subchannels (changed to vendor parameter) February 2010 Removed subchannels (changed to vendor parameter) February 2010 Removed subchannels-number (changed to vendor parameter) and startallocation (obsolete-hard coded to 0).
Document History Topic Description Date Issued Displaying Configuration Information for Airframe Uplink Data Zone Parameters Removed subchannels-number and startallocation. February 2010 Removed max-cqi (changed to vendor parameter) February 2010 Removed linkusage-hardthrshld and mtu (changed to vendor parameters). February 2010 Section 3.9.12.5.6 Managing BS Feedback Allocation Parameter Section 3.9.5 Managing BS Bearer Interface Parameters Section 3.9.
Document History Topic Description Date Issued Mapping of Macro Outdoor BTS AUs to Slot # Corrected mapping February 2010 Removed Trigger Setup parameters. February 2010 Managing Trigger Setup Parameters Removed February 2010 Displaying Configuration and Status Information for ODU Ports Added new read-only parameters February 2010 Table 3-1 Managing Neighbor BSs Appendix 3.9.9 Section 3.7.2.
Document History Topic Description Date Issued Configuring Parameters for IP-IP Service Interface Updated Description, Presence and Default Value for srcaddr and dstaddr. February 2010 Updated Description, Presence and Default Value for vlan-id and dflt-gw-ip. February 2010 Updated default value of opt60. February 2010 Updated default value of opt60. February 2010 Updated Description, Presence and Default Value of server-addr.
Document History Topic Description Date Issued Displaying the VLAN Translation Entries Updated command syntax April 2010 New feature April 2010 Updated description and default value of ul-99prcntnoise.
Document History Topic Description Date Issued Configuring Parameters for the PHS Rule Corrected definition for verify (in Possible Values) Section 3.4.12.12.2 Displaying System-level Logs Updated command syntax Section 3.4.13.1.3 Configuring the Position Updated command syntax Section 3.4.16.2.5 Managing Neighbor BSs, Section 3.9.
Legal Rights Legal Rights © Copyright 2010 Alvarion Ltd. All rights reserved. The material contained herein is proprietary, privileged, and confidential and owned by Alvarion or its third party licensors. No disclosure thereof shall be made to third parties without the express written permission of Alvarion Ltd. Alvarion Ltd. reserves the right to alter the equipment specifications and descriptions in this publication without prior notice.
Legal Rights (b) With respect to the Firmware, Alvarion warrants the correct functionality according to the attached documentation, for a period of fourteen (14) month from invoice date (the "Warranty Period")". During the Warranty Period, Alvarion may release to its Customers firmware updates, which include additional performance improvements and/or bug fixes, upon availability (the "Warranty"). Bug fixes, temporary patches and/or workarounds may be supplied as Firmware updates.
Legal Rights FULLEST EXTENT ALLOWED BY LAW, THE WARRANTIES AND REMEDIES SET FORTH IN THIS AGREEMENT ARE EXCLUSIVE AND IN LIEU OF ALL OTHER WARRANTIES OR CONDITIONS, EXPRESS OR IMPLIED, EITHER IN FACT OR BY OPERATION OF LAW, STATUTORY OR OTHERWISE, INCLUDING BUT NOT LIMITED TO WARRANTIES, TERMS OR CONDITIONS OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, SATISFACTORY QUALITY, CORRESPONDENCE WITH DESCRIPTION, NON-INFRINGEMENT, AND ACCURACY OF INFORMATION GENERATED.
Legal Rights FCC Radiation Hazard Warning To comply with FCC RF exposure requirements in Section 1.1307 and 2.1091 of FCC Rules, the antenna used for this transmitter must be fixed-mounted on outdoor permanent structures with a separation distance of at least 2 meter from all persons. R&TTE Compliance Statement This equipment complies with the appropriate essential requirements of Article 3 of the R&TTE Directive 1999/5/EC.
Legal Rights The equipment must be connected directly to the DC Supply System grounding electrode conductor. All equipment in the immediate vicinity must be grounded in the same way, and not be grounded elsewhere. The DC supply system is to be local, i.e. within the same premises as the equipment. There shall be no disconnect device between the grounded circuit conductor of the DC source (return) and the point of connection of the grounding electrode conductor.
Legal Rights regulation violations associated with or caused by installation, grounding or lightning protection. Disposal of Electronic and Electrical Waste Disposal of Electronic and Electrical Waste Pursuant to the WEEE EU Directive electronic and electrical waste must not be disposed of with unsorted waste. Please contact your local recycling authority for disposal of this product.
Important Notice Important Notice This user manual is delivered subject to the following conditions and restrictions: This manual contains proprietary information belonging to Alvarion Ltd. Such information is supplied solely for the purpose of assisting properly authorized users of the respective Alvarion products.
Important Notice damage and/or bodily harm and/or void the user's authority to operate the equipment and/or revoke the warranty provided by such manufacturer.
About This Manual About This Manual This manual describes the 4Motion solution, and details how to install, operate and manage the BTS system components. This manual is intended for technicians responsible for installing, setting and operating the 4Motion BTS equipment, and for system administrators responsible for managing the system. This manual contains the following chapters and appendices: Chapter 1 - System description: Describes the 4Motion BTS and its components.
Contents Contents Chapter 1 - System Description .............................................................. 1 1.1 About WiMAX................................................................................................................3 1.2 4Motion Solution ..........................................................................................................4 1.2.1 4Motion Solution Highlights.................................................................................4 1.2.
Contents 1.5.8 Standards Compliance, General .......................................................................43 1.5.9 Environmental ...................................................................................................43 1.5.10 Mechanical and Electrical .................................................................................44 1.5.11 Antennas ...........................................................................................................
Contents 3.1.2 Accessing the CLI .............................................................................................75 3.1.3 Command Modes..............................................................................................78 3.1.4 Interpreting the Command Syntax ....................................................................79 3.1.5 Using the CLI ....................................................................................................80 3.1.
Contents 3.4.12 Configuring the ASN-GW Functionality...........................................................230 3.4.13 Configuring Logging ........................................................................................385 3.4.14 Configuring Performance Data Collection.......................................................402 3.4.15 Configuring the SNMP/Trap Manager.............................................................406 3.4.16 Configuring the 4Motion Shelf...............................
Contents 3.9.1 Enabling the BS Configuration Mode\Creating a BS Object ...........................496 3.9.2 Deleting a BS ..................................................................................................497 3.9.3 Managing BS General Parameters .................................................................498 3.9.4 Managing Power Control Levels .....................................................................506 3.9.5 Managing BS Feedback Allocation Parameter ........................
Contents 3.9.26 Managing Beam Forming Parameter ..............................................................642 3.10Managing Sectors ....................................................................................................646 3.10.1 Configuring Sector Parameters.......................................................................646 3.10.2 Configuring Sector Association Entries...........................................................655 3.11Monitoring HW and SW Components .................
Contents 4.6.2 Sector Association ..........................................................................................706 4.7 BS Menu ....................................................................................................................708 4.7.1 Add..................................................................................................................708 4.7.2 Select ..............................................................................................................
Chapter 1 System Description
Chapter 1 - System Description In This Chapter: “About WiMAX” on page 3 “4Motion Solution” on page 4 “The Base Transceiver Station” on page 13 “Element Management Systems” on page 25 “Specifications” on page 27 4Motion 2 System Manual
Chapter 1 - System Description 1.1 About WiMAX About WiMAX Emanating from the broadband world and using all-IP architecture, mobile WiMAX is the leading technology for implementing personal broadband services. With huge market potential and affordable deployment costs, mobile WiMAX is on the verge of a major breakthrough.
Chapter 1 - System Description 4Motion Solution 1.2 4Motion Solution 1.2.1 4Motion Solution Highlights Leveraging its extensive experience in Broadband Wireless Access (BWA) systems, leading technology and current favorable economics for broadband and mobile services, Alvarion's 4Motion mobile WiMAX solution represents the next evolution in communications. With 4Motion, Alvarion offers a diversified range of products and services for all operators.
Chapter 1 - System Description 4Motion Solution BTS (Base Transceiver Station) equipment with an optional localized access service network gateway (ASN-GW): » Indoor modular Macro BTS. » All-outdoor modular Macro BTS.
Chapter 1 - System Description 4Motion Solution Alvarion believes that compliance with standard-driven open architecture protects the infrastructure investment, and opens the system to a variety of fully interoperable end-user devices. As such, 4Motion is designed with open architecture and interfaces according to the WiMAX Forum networking working group (NWG) profile C, which supports openness and enables flat as well as hierarchical topologies.
Chapter 1 - System Description 4Motion Solution Figure 1-3: ASN Reference Model containing Multiple ASN-GWs The various components and entities involved in the networking architecture are: 1.2.2.1 Access Service Network (ASN) An ASN is defined as a complete set of network functions needed to provide radio access to a WiMAX subscriber.
Chapter 1 - System Description 4Motion Solution An ASN is comprised of network elements such as one or more base transceiver stations and one or more ASN gateways. An ASN may be shared by more than one connectivity service network (CSN). 1.2.2.2 Connectivity Service Network (CSN) A CSN is defined as a set of network functions that provide IP connectivity services to WiMAX subscribers.
Chapter 1 - System Description 4Motion Solution third-party application providers (e.g. ASP, ISP) for the delivery of WiMAX services to subscribers. From a WiMAX subscriber standpoint, an NSP may be classified as a home or visited NSP. 1.2.2.5 Base Station (BS) The WiMAX BS is an entity that implements the WiMAX MAC and PHY in compliance with the IEEE 802.16e standard. A BS operates on one frequency assignment, and incorporates scheduler functions for uplink and downlink resources.
Chapter 1 - System Description 4Motion Solution QoS service flow authorization entity AAA accounting client The basic EP functionality of the ASN-GW includes: Classification of downlink data into generic routing encapsulation (GRE) tunnels Packet header suppression functionality DHCP functionality Handover functionality The WIMAX Forum NWG has adopted two different approaches for ASN architecture - centralized and distributed: In the centralized approach there is at least one central ASN-GW, a
Chapter 1 - System Description 4Motion Solution In the distributed approach, the NPU operates in ASN-GW mode, as shown in Figure 1-5. Figure 1-5: Distributed Network Reference Model Alvarion believes in providing operators with the flexibility to select the mobile WiMAX network topology that best suits their needs and existing network architecture. Therefore, 4Motion is designed to support both distributed and centralized topology approaches according to WiMAX Forum NWG profile C. 1.2.2.
Chapter 1 - System Description 4Motion Solution Reference point R3 consists of the set of control plane protocols between the ASN and CSN to support AAA, policy enforcement and mobility management capabilities. It also encompasses the bearer plane methods (e.g. tunneling) to transfer user data between the ASN and CSN.
Chapter 1 - System Description 1.3 The Base Transceiver Station The Base Transceiver Station The 4Motion solution features a multi-carrier, high-power Base Transceiver Station (BTS). Designed for high availability and redundancy, it utilizes a central networking and management architecture, and a range of diversity schemes. The BTS main features include: R1 support - 802.16e interface handling (e.g.
Chapter 1 - System Description The Base Transceiver Station 1.3.1 The Indoor Macro BTS 1.3.1.1 The BreezeMAX Shelf The BreezeMAX shelf is an indoor -48 VDC powered 8U cPCI PICMG 2.x standard shelf prepared for installation in a 19" or 21" (ETSI) rack. This chassis has a total of nine double-Euro (6U high) slots and six single-Euro (3U high) slots. All the modules are hot swappable, and high availability can be provided through multiple redundancy schemes.
Chapter 1 - System Description The Base Transceiver Station Table 1-1: BreezeMAX Shelf Modules Module Description AU 6U high access unit, 4-channel, 802.16e MAC-modem-baseband IF card AVU 2U high air ventilation unit, 9+1 redundancy fans with alarm control The six single-Euro slots are intended for one or two redundant Power Interface Units (PIUs) and up to four redundant Power Supply Units (PSUs).
Chapter 1 - System Description The Base Transceiver Station L2 switch forwarding capabilities Internal and external traffic VLAN encapsulation QoS marking Overall operation, control and shelf management, including AU diagnostics and control, PSU monitoring, AVU management and redundancy support Local and remote extensive management support via CLI (Telnet, SSH) and SNMP, including software download, fault and performance management Alarm management, including external alarm inputs and activati
Chapter 1 - System Description The Base Transceiver Station Handover functionality GRE encapsulation/decapsulation IP-in-IP encapsulation/decapsulation Transparent VLAN (single tag) and QinQ (dual tag) encapsulation Fragmentation/reassembly R4/R6/R3 interfaces implementation Keep-alive signaling towards the relevant BSs and other ASN-GWs for enhanced management of service availability When several shelves are collocated, the NPU cascade interface can be used for shelf interconnection.
Chapter 1 - System Description The Base Transceiver Station Wide variety of reuse patterns Advanced channel coding (CTC) HARQ Rate adaptation High-performance CDMA detector IF interface to RF ODU MAC-PHY interface Link management (network entry, basic capabilities negotiation, authentication and registration, connection management) Fragmentation/ reassembly QoS PEP for air interface traffic QoS DSCP marking Scheduling - connections quota computation for all data delivery types Fr
Chapter 1 - System Description The Base Transceiver Station Context client/server ID to IP address resolution for ASN entities IP and Ethernet convergence sublayers Keep-alive signaling towards the relevant ASN-GWs for enhanced management of service availability The AU design is based on Alvarion's programmable, off-the-shelf, cutting-edge components, in order to provide a future-proof solution with excellent cost and performance.
Chapter 1 - System Description The Base Transceiver Station Table 1-2: PSU Requirements, Configurations with one NPU (excluding PSU redundancy) 1.3.1.6 Number of AUs Minimum Required Number of PSUs 1-4 2 5-6 3 AVU The 2U-high AVU includes a 1U-high integral chamber for inlet airflow and a 1U-high fan tray with an internal alarm module. To support high availability, the fan tray includes 10 brushless fans (9 fans are sufficient for cooling a fully-loaded shelf).
Chapter 1 - System Description 1.3.3 The Base Transceiver Station The Outdoor Micro BTS Micro Outdoor BTS is a full-outdoor small form factor WiMAX Base Transceiver Station. The Micro Outdoor BTS complements Macro BTS deployments providing white spots coverage, cell extension and capacity boost. It provides excellent cost/performance in addressing low dense population areas (rural & suburban).
Chapter 1 - System Description The Base Transceiver Station Table 1-3: ODU Types Band (GHz) ODU Frequency Range (MHz) ODU Port Configuration ODU Bandwidth (MHz) ODU Max Tx Power (dBm) BF Support 2.
Chapter 1 - System Description The Base Transceiver Station Feeder unit can serve up to four ODUs. Up to three ODU Power Feeder units can be installed in a 1U high Power Feeder panel. 1.3.6 Antenna In the 4Motion architecture, the antenna is approached as an independent element. This provides the operator with the flexibility to select the antennas source according to its supplier policy.
Chapter 1 - System Description The Base Transceiver Station Alvarion offers the miniature GPS antenna that can be installed at a distance of up to 3m from the BTS.
Chapter 1 - System Description 1.4 Element Management Systems Element Management Systems The end-to-end IP-based architecture of the system enables full management of all components, using standard management tools. An SNMP agent in the NPU implements proprietary MIBs for remote setting of operational modes and parameters of the Base Transceiver Station equipment. Security features incorporated in the equipment restrict the access for management purposes.
Chapter 1 - System Description Element Management Systems Device embedded software upgrade BTS duplication and template-based configuration modification of multiple BTS simultaneously. Security Management Event Forwarding to other Network Management Systems.
Chapter 1 - System Description Specifications 1.5 Specifications 1.5.1 Modem & Radio Table 1-4: General Modem & Radio Specifications Item Description Operation Mode TDD Channel Bandwidth 5 MHz 7 MHz (not applicable for the 2.x GHz band) 10 MHz 1.5.2 Central Frequency Resolution 0.
Chapter 1 - System Description Specifications 1.5.3 ODUs 1.5.3.1 2.3 GHz Band 1.5.3.1.1 2.3 GHz Band 1x1 ODUs Table 1-6: 2.3 GHz Band 1x1 ODUs Specifications Item Description Frequency Band ODU-HP-2.3: 2300-2360 MHz ODU-HP-2.3-WCS: 2305 - 2317, 2348 - 2360 MHz (includes WCS filter) ODU-HP-2.
Chapter 1 - System Description 1.5.3.1.2 Specifications 2.3 GHz Band 2x2 ODU Table 1-7: 2.3 GHz Band 2x2 ODU Specifications Item Description Frequency Band ODU-2300-2400-000N-38-2X2-N-0: 2300-2400 MHz* Ports Configuration 2x2 (2Rx, 2Tx) Bandwidth Support Up to 30 MHz Beam Forming Support Yes Maximum Tx Power) 38 dBm* Tx Power Control Range 10 dB, in 1 dB steps Tx Power Accuracy +/- 1 dB Maximum Input Power @ antenna port -60 dBm before saturation, -8 dBm before damage Noise Figure 4.
Chapter 1 - System Description Specifications 1.5.3.2 2.5 GHz Band 1.5.3.2.1 2.5 GHz Band 1x1 ODUs Table 1-8: 2.5 GHz Band 1x1 ODUs Specifications Item Description Frequency Band ODU-HP-2.5A: 2496-2602 MHz (Band A) ODU-HP-2.
Chapter 1 - System Description 1.5.3.2.2 Specifications 2.5 GHz Band 2x2 ODUs Table 1-9: 2.5 GHz Band 2x2 ODUs Specifications Item Description Frequency Band ODU-2485-2690-000N-38-2X2-N-0: 2485-2690 MHz Ports Configuration 2x2 (2Rx, 2Tx) Bandwidth Support Up to 30 MHz Beam Forming Support Yes Maximum Tx Power) 38 dBm Tx Power Control Range 10 dB, in 1 dB steps Tx Power Accuracy +/- 1 dB Maximum Input Power @ antenna port -60 dBm before saturation, -8 dBm before damage Noise Figure 4.
Chapter 1 - System Description 1.5.3.2.3 Specifications 2.5 GHz Band 4x2 ODUs Table 1-10: 2.
Chapter 1 - System Description Specifications maximum Tx power of 33 dBm and without support of beam forming capability. b If you use ODU-2485-2690-000-N-38-4x2-N-0: Configure oDU24962602000N334by2EtsiBFN0 as the required type. This will create a “virtual” ODU supporting the frequency range 2496-2602 MHz with a maximum Tx power of 33 dBm and support of beam forming capability. c If you use ODU-2485-2690-000-N-38-2x2-N-0: Configure oDU24962602000N332by2EtsiBFN0 as the required type.
Chapter 1 - System Description Specifications 1.5.3.3 3.3 GHz Band 1.5.3.3.1 3.3 GHz Band 1x1 ODUs Table 1-11: 3.
Chapter 1 - System Description Specifications 1.5.3.4 3.5 GHz Band 1.5.3.4.1 3.5 GHz Band 1x1 ODUs Table 1-12: 3.5 GHz Band 1x1 ODUs Specifications Item Description Frequency Band ODU-HP-TDD-3.4a: 3400-3455 MHz ODU-HP-TDD-3.4b: 3445-3500 MHz ODU-HP-TDD-3.5a: 3500-3555 MHz ODU-HP-TDD-3.
Chapter 1 - System Description 1.5.3.4.2 Specifications 3.5 GHz Band 2x2 ODUs Table 1-13: 3.5 GHz Band 2x2 ODUs Specifications Item Description Frequency Band ODU-3400-3600-000N-37-2x2-N-0: 3400-3600 MHz Ports Configuration 2x2 (2Rx, 2Tx) Bandwidth Support Up to 30 MHz Beam Forming Support Yes Maximum Tx Power) 37 dBm Tx Power Control Range 10 dB, in 1 dB steps Tx Power Accuracy +/- 1 dB Maximum Input Power @ antenna port -60 dBm before saturation, -8 dBm before damage Noise Figure 4.
Chapter 1 - System Description 1.5.3.4.3 Specifications 3.5 GHz Band 4x2 ODUs Table 1-14: 3.
Chapter 1 - System Description Specifications 1.5.3.5 3.6 GHz Band 1.5.3.5.1 3.6 GHz Band 1x1 ODU Table 1-15: 3.6 GHz Band 1x1 ODU Specifications Item Description Frequency Band ODU-3650-3700-000N-22-1x1-N-0: 3650-3700 MHz Ports Configuration 1x1 (1Rx, 1Tx) Bandwidth Support Up to 14 MHz Maximum Tx Power 22 dBm Tx Power Control Range 10 dB, in 1 dB steps Tx Power Accuracy +/- 1 dB Maximum Input Power @ antenna port -60 dBm before saturation, -8 dBm before damage Noise Figure 4.
Chapter 1 - System Description 1.5.3.5.2 Specifications 3.6 GHz Band 4x2 ODU Table 1-16: 3.6 GHz Band 4x2 ODU Specifications Item Description Frequency Band ODU-3600-3800-000N-36-4x2-N-0: 3600-3800 MHz Ports Configuration 4x2 (4Rx, 2Tx) Bandwidth Support Up to 20 MHz Beam Forming Support Yes Maximum Tx Power) 36 dBm Tx Power Control Range 10 dB, in 1 dB steps Tx Power Accuracy +/- 1 dB Maximum Input Power @ antenna port -60 dBm before saturation, -8 dBm before damage Noise Figure 4.
Chapter 1 - System Description 1.5.4 Specifications Micro Outdoor BTS Table 1-17: Micro Outdoor BTS Specifications Item Description Frequency 2.5 GHz Band: 2485-2690 MHz 3.5 GHz Band: 3400-3600 MHz Bandwidth Support Up to 20 MHz Maximum Tx Power 36 dBm Tx Power Control Range 10 dB, in 1 dB steps Tx Power Accuracy +/- 1 dB Max. Input Power (at antenna port) -40 dBm before saturation Dimensions (H x W x D) 511 x 280 x 216 mm Weight (kg) 17.5 Power Source -40.
Chapter 1 - System Description 1.5.5 Specifications AU - ODU Communication (Macro BTS) Table 1-18: AU - ODU Communication Item Description IF Frequency Tx: 240 MHz Rx: 140 MHz Ref Synchronization Frequency 64 MHz Bi-Directional Control Frequency 14 MHz IF cable Impedance 50 Ohm Maximum IF cable Attenuation 10 dB @ 240 MHz 7.
Chapter 1 - System Description 1.5.
Chapter 1 - System Description 1.5.8 Specifications Standards Compliance, General Table 1-21: Standards Compliance, General Type Standard EMC ETSI EN 301 489-1/4 FCC Part 15 EN60950-1 Safety UL 60950-1 Environmental ETS 300 019: Part 2-1 T 1.2 & part 2-2 T 2.3 for indoor & outdoor Part 2-3 T 3.2 for indoor Part 2-4 T 4.1E for outdoor ETSI EN 302 326 Radio ETSI EN 302 544 FCC part 15, part 27, part 25 1.5.
Chapter 1 - System Description Specifications 1.5.10 Mechanical and Electrical 1U = 44.45 mm (1.75”). 1HP = 5.08 mm (0.
Chapter 1 - System Description Specifications 1.5.10.1 Macro Indoor BTS 1.5.10.1.1 BreezeMAX Shelf Table 1-23: BreezeMAX Shelf, Mechanical & Electrical Specifications 1.5.10.1.2 Item Description Dimensions 8U ETSI type shelf, 8U x 43.2 x 24 cm Weight 6.5 Kg (including AVU) AVU Table 1-24: AVU, Mechanical & Electrical Specifications 1.5.10.1.3 Item Description Dimensions 2U x 84HP x 16 cm Weight 1.
Chapter 1 - System Description 1.5.10.1.5 Specifications NPU Table 1-27: NPU, Mechanical & Electrical Specifications Item Description Dimensions 6U x 7HP x 16 cm Weight 0.55 Kg Power Consumption 68W maximum, 61W typical Connectors 1.5.10.1.
Chapter 1 - System Description Specifications 1.5.10.2 Macro Outdoor BTS 1.5.10.2.1 NAU Table 1-29: NAU, Mechanical & Electrical Specifications Item Description Dimensions 420 x 340 x 270 mm Weight 17 Kg (excluding mounting kit) Power Source -40.5 to -60 VDC Power Consumption 140W maximum NPU Connectors AU Connectors 1.5.10.2.
Chapter 1 - System Description 1.5.10.2.3 Specifications DAU Table 1-31: DAU, Mechanical & Electrical Specifications Item Description Dimensions 420 x 340 x 270 mm Weight 17 Kg (excluding mounting kit) Power Source -40.
Chapter 1 - System Description Specifications 1.5.10.4 GPS Receiver for Macro BTS 1.5.10.4.1 BMAX-Timing GPS-OGR Specifications Table 1-33: BMAX-Timing GPS-OGR GPS Receiver, Mechanical & Electrical Specifications 1.5.10.4.2 Item Description Dimensions Tubular enclosure, 15.5 D x 12.7 H cm Weight 0.
Chapter 1 - System Description Specifications Table 1-36: ODU Power Feeder, Mechanical & Electrical Specifications Item Description Power Source -40.
Chapter 1 - System Description Specifications 1.5.11 Antennas 1.5.11.1 2.x GHz Antennas Table 1-37: BS-RET-DP-ANT 2.3-2.7 Specifications 4Motion Item Description Frequency Band (MHz) 2300-2700 Number of Elements 2 Polarization Linear, +/-45° Gain (dB) 17.3 @ 2.4 GHz 18 @ 2.6 GHz Azimuth Beamwidth (degrees) 65 Elevation Beamwidth (degrees) 6.
Chapter 1 - System Description Specifications Table 1-38: BS-RET-DDP-ANT 2.3-2.7 and BS-EDT-DDP-ANT 2.3-2.7 Specifications Item Description Frequency Band (MHz) 2300-2700 Number of Elements 4 Polarization Linear, 2 x +/-45° Gain (dB) 17.3 @ 2.4 GHz 18 @ 2.6 GHz Azimuth Beamwidth (degrees) 65 Elevation Beamwidth (degrees) 6.
Chapter 1 - System Description Specifications Table 1-39: ANT.2.3-2.7GHz, D/S,65°,16±0.5dBi Specifications Item Description Frequency Band (MHz) 2300-2700 Number of Elements 2 Polarization Linear, +/-45° Gain (dB) 16 +/- 0.
Chapter 1 - System Description 1.5.11.2 Specifications 3.5 GHz Antennas Table 1-40: BS-RET-DP-ANT 3.3-3.8 Specifications 4Motion Item Description Frequency Band (MHz) 3300-3800 Number of Elements 2 Polarization Linear, +/-45° Gain (dB) 18 Azimuth Beamwidth (degrees) 65 Elevation Beamwidth (degrees) 6.
Chapter 1 - System Description Specifications Table 1-41: BS-RET-DDP-ANT 3.3-3.8 Specifications 4Motion Item Description Frequency Band (MHz) 3300-3800 Number of Elements 4 Polarization Linear, 2 x +/-45° Gain (dB) 18 Azimuth Beamwidth (degrees) 65 Elevation Beamwidth (degrees) 6.
Chapter 1 - System Description Specifications Table 1-42: ANT.3.5GHz, D/S,65°,16±0.5dBi Specifications Item Description Frequency Band (MHz) 3300-3800 Number of Elements 2 Polarization Linear, +/-45° Gain (dB) 16 +/- 0.
Chapter 2 Commissioning of the Macro BTS
Chapter 2 - Commissioning of the Macro BTS In This Chapter: “Initial NPU Configuration” on page 59 “Completing the Site Configuration Using AlvariSTAR” on page 63 4Motion 58 System Manual
Chapter 2 - Commissioning of the Macro BTS Initial NPU Configuration 2.1 Initial NPU Configuration 2.1.1 Introduction After completing the installation process, as described in the preceding chapter, some basic NPU parameters must be configured locally using the CLI via the MON port of the NPU. Refer to “Using the Command Line Interface” on page 73 for information on how to access the CLI either via the MON port or via Telnet and how to use it.
Chapter 2 - Commissioning of the Macro BTS Initial NPU Configuration The default connectivity mode is In-Band (IB) via the Data port. Alternatively, the NPU can be managed Out-Of-Band (OOB) via the dedicated Management port. To view the current and configured connectivity mode, use the command: npu# show connectivity mode To change the connectivity mode to Out-Of-Band, use the command: npu(config)# connectivity mode outband (for details refer to “Configuring the IP Connectivity Mode” on page 125). 2.1.3.
Chapter 2 - Commissioning of the Macro BTS 2.1.3.
Chapter 2 - Commissioning of the Macro BTS 2 Initial NPU Configuration npu(config)# trap-mgr enable ip-source x.x.x.x Note that if the management system is behind a NAT router, the NAT Outside IP address (the IP of the router’s interface connected in the direction of the managed device LAN) must be defined in the device as a Trap Manager, with traps sending enabled.
Chapter 2 - Commissioning of the Macro BTS Completing the Site Configuration Using AlvariSTAR 2.2 Completing the Site Configuration Using AlvariSTAR 2.2.1 Introduction After completion of the initial configuration you should be able to manage the new Site using AlvariSTAR and continue configuring (at least) all mandatory parameters to enable the necessary services. For details on how to use AlvariSTAR for managing 4Motion sites refer to the AlvariSTAR and 4Motion Device Manager User Manuals.
Chapter 2 - Commissioning of the Macro BTS 2.2.2 Site Configuration 2.2.2.1 General Tab Completing the Site Configuration Using AlvariSTAR ASN Topology - the default is Distributed ASNGW. If you change it to Centralized ASNGW click Apply for the device to accept the change. 2.2.3 Connectivity Configuration (optional) 2.2.3.1 IP Interface Screen Configure the IP address of the Bearer interface: 2.2.3.2 1 Change the IP and/or any other parameter value, except VLAN ID.
Chapter 2 - Commissioning of the Macro BTS 2 2.2.4.2 Completing the Site Configuration Using AlvariSTAR In the New AU definition window, define the following: » AU number (AU Slot) » Type (in current release only AU 4x4 Modem is applicable) 3 Click Apply. 4 Repeat the process for all required AU entities. ODU ODU entities must be created for all installed ODUs (you may create an ODU entity also for ODUs that are not installed yet).
Chapter 2 - Commissioning of the Macro BTS 2.2.4.4 Completing the Site Configuration Using AlvariSTAR 3 Click Apply. 4 Repeat the process for all required Antenna entities. GPS The default GPS Type is Trimble. If there is no GPS, the value should be changed to None. Click Apply for the device to accept the change. 2.2.5 ASNGW Configuration NOTE ASNGW screens are available only for Distributed ASNGW topology (see also “Site Configuration” on page 64. 2.2.5.
Chapter 2 - Commissioning of the Macro BTS 2 2.2.5.2.2 Completing the Site Configuration Using AlvariSTAR Click Apply for the device to accept the configuration. Service Groups Tab At least one Service Group associated with a defined Service Interface for data must be defined. If a dedicated management station for CPEs is being used, a suitable Service Group associated with the defined Service Interface for management must also be defined.
Chapter 2 - Commissioning of the Macro BTS 3 Completing the Site Configuration Using AlvariSTAR The new Service Profile added to the list of available Service Profiles in the navigation tree. Select it to continue the configuration process. 4 Click Add in the Service Flow area. 5 Configure the applicable general parameters of the Service Flow.
Chapter 2 - Commissioning of the Macro BTS Completing the Site Configuration Using AlvariSTAR 2 Click Apply for the device to accept the configuration. 3 You will be prompted to properly configure some additional parameters. 4 Click Apply for the device to accept the configuration. 5 Select the Radio Advanced screen and click Apply to complete the configuration. 2.2.6.3 R6/R8 Bearer Interface 2.2.6.3.1 Bearer Tab 1 2 2.2.6.3.2 2.2.
Chapter 2 - Commissioning of the Macro BTS 4 Completing the Site Configuration Using AlvariSTAR At least one Site Sector Association must be defined for each Site Sector. Click on the Add Sector Association button and configure all the parameters in the applicable line of the Sector site Association table: 5 2.2.8 » BS ID LSB » AU Slot Number » AU Port Number » ODU Number » ODU Port Number » Antenna Number » Antenna Port Number Click Apply for the device to accept the configuration.
Chapter 3 Operation and Administration of the Macro BTS
Chapter 3 - Operation and Administration of the Macro BTS In This Chapter: “Using the Command Line Interface” on page 73 “Managing Software Upgrade” on page 99 “Shutting Down/Resetting the System” on page 119 “NPU Configuration” on page 122 “Managing MS in ASN-GW” on page 450 “Managing AUs” on page 454 “Managing ODUs” on page 469 “Managing Antennas” on page 485 “Managing BSs” on page 493 “Managing Sectors” on page 646 “Monitoring HW and SW Components” on page 660 “Troubleshooting” o
Chapter 3 - Operation and Administration of the Macro BTS 3.1 Using the Command Line Interface Using the Command Line Interface All 4Motion system components are managed via the NPU module. The AU is not accessed directly: any configuration change or status enquiry is sent to the NPU that communicates with other system components.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface “Managing Secure Shell (SSH) Parameters” on page 92 “Managing the Session” on page 94 3.1.1 Managing the Macro Outdoor BTS The following section describe the CLI when using it to manage the Indoor Macro BTS equipment. The same CLI is used also to manage the Macro Outdoor BTS equipment, with the following changes: 3.1.1.1 CSCD Port and Local Management There is no CSCD port in the Macro Outdoor BTS.
Chapter 3 - Operation and Administration of the Macro BTS 3.1.1.6 Using the Command Line Interface AUs Up to a maximum of six AUs can be supported in the Macro Outdoor BTS. The following table details the mapping of Macro Outdoor BTS AUs to Slot numbers: Table 3-1: Mapping of Macro Outdoor BTS AUs to Slot # 3.1.1.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface Table 3-2: COM Port Configuration 4 Parameter Value Baud rate 115200 Data bits 8 Stop bits 1 Parity None Flow control Xon/Xoff Port Connected COM port The login prompt is displayed. (Press Enter if the login prompt is not displayed.) Enter your login ID and password to log in to the CLI.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface IMPORTANT The in-band connectivity mode is the default connectivity mode; the DATA port and external-management VLAN are the default Ethernet port and IP interface that are configured for the in-band connectivity mode. The following procedure can be used for accessing the CLI when the in-band connectivity mode is selected. This procedure is identical for all other connectivity modes.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface NOTE The default login ID and password are: Login ID: admin Password: admin123 After you provide your login information, the following command prompt is displayed: npu# This is the global command mode. For more information about different command modes, refer to Section 3.1.3. 3.1.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface Table 3-4: Commands to Enter/Exit a Command Mode Enter the interface configuration mode npu(config)# interface Exit the configuration mode and enter the global command mode. npu(config)# end npu# npu (config-if)# end npu# Exit the current configuration mode by one level npu (config-if)# exit npu(config)# 3.1.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface Table 3-5: Conventions Used in the 4Motion Command Syntax [] <> | Indicates that the parameter enclosed within these brackets is optional. npu(config)# reboot from shadow [] Indicates that the parameter is mandatory and requires a user-defined value (and not a discrete value).
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface “Using Miscellaneous Commands” on page 82 “Privilege Levels” on page 82 3.1.5.1 Using Control Characters Control characters refer to special characters that you can use to recall or modify previously-executed commands. The following table lists the control characters to be used for executing commands on the CLI: Table 3-6: Control Characters for Using the CLI Press To...
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface If you do not provide the command name as the parameter, all commands that can be executed in the current command mode are displayed. 3.1.5.3 Using the History Feature The history feature of the CLI maintains a sequential list of all previously executed commands.
Chapter 3 - Operation and Administration of the Macro BTS 3.1.6 Using the Command Line Interface Managing Users and Privileges To enable multi-level access to the CLI, you can create and manage multiple users, and assign privilege levels for each user. The privilege level determines whether a user is authorized to execute a particular command. The privilege level is pre-configured for each command, and can be between 1 and 10, where 1 is the lowest and 10 is the highest.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface “Deleting a User” on page 85 3.1.6.1.1 Adding/Modifying Users IMPORTANT Only users who have logged in as admin can execute this task. To add/modify a user, and assign a username, password, and privilege level, run the following command: npu(config)# username password privilege <1-10> IMPORTANT An error may occur if: You are not logged in as the admin.
Chapter 3 - Operation and Administration of the Macro BTS privilege <1-10> Command Modes 3.1.6.1.2 Indicates the privilege level to be assigned to a user. The user will be permitted to execute all commands for which the privilege level is equal to or lower than the value of this parameter. Using the Command Line Interface Mandatory N/A 1-10 Global configuration mode Deleting a User IMPORTANT Only users who have logged in as admin can execute this task.
Chapter 3 - Operation and Administration of the Macro BTS Syntax Description Command Modes 3.1.6.2 Using the Command Line Interface Parameter Description Presence Default Value Possible Values username Indicates the username of the user to be deleted.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface IMPORTANT An error may occur if: You are trying to configure a password for a privilege level that is higher than your default privilege level. The password that you have specified is more than 20 characters. The privilege level that you have specified is not within the range, 1-10. Command Syntax npu(config)# enable password Privilege Level 10 Syntax Description Command Modes 3.1.6.2.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface IMPORTANT An error may occur if: The privilege level that you have specified is not within the range, 1-10. You are trying to delete a password for a privilege level that is higher than your default privilege level. Command Syntax npu(config)# no enable password [Level <1-10>] Privilege Level 10 Syntax Description Command Syntax 3.1.6.
Chapter 3 - Operation and Administration of the Macro BTS 3.1.6.3.1 Using the Command Line Interface Enabling a Higher Privilege Level To enable a higher privilege level: 1 Log in to the CLI. 2 Run the following command to specify the privilege level and password: npu(config)# enable [Level <1-10>] 3 At the password prompt, specify the password configured for the privilege level that you have specified.
Chapter 3 - Operation and Administration of the Macro BTS Syntax Description Command Modes 3.1.6.3.2 Using the Command Line Interface Parameter Description Presence Default Value Possible Values [Level <1-10>] Indicates the privilege level you want to enable.
Chapter 3 - Operation and Administration of the Macro BTS Command Syntax npu# show users Privilege Level 1 Display Format Line Command Syntax Global command mode 3.1.6.5 0 con User Using the Command Line Interface Peer Address Displaying All Users To display all users, run the following command: npu# listuser Command Syntax npu# listuser Privilege Level 1 Display Format User Mode User 1 User 2 User 3 Command Syntax 3.1.6.
Chapter 3 - Operation and Administration of the Macro BTS Command Syntax npu# show privilege Privilege Level 1 Display Format Current privilege level is Command Syntax Global command mode 3.1.7 Using the Command Line Interface Managing Secure Shell (SSH) Parameters The SSH parameters define the parameters used for establishing remote secure access to the device using SSH protocol rather than the plaintext-based insecure Telnet protocol.
Chapter 3 - Operation and Administration of the Macro BTS Syntax Description Using the Command Line Interface Parameter Description Presence Default Value Possible Values version compatibility The SSH version that can be used: The default is SSH version 2. The command Optional SSH2 version compatibility des-cbc des-cbc npu(config)# ip ssh version compatibility enables compatibility with both SSH version 1 and SSH version 2. Command Modes 3.1.7.
Chapter 3 - Operation and Administration of the Macro BTS 3.1.7.3 Using the Command Line Interface Displaying the SSH Parameters To display the current configuration of the SSH parameters, run the following command: npu# show ip ssh Command Syntax npu# show ip ssh Privilege Level 1 Display Format Version : Cipher Algorithm : Authentication : Command Modes 3.1.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface To resume the session, you must enter the password used for initiating it. Command Syntax npu# lock Privilege Level 10 Command Modes Global command mode 3.1.8.2 Managing the Session Timeout The session timeout parameter defines the maximum allowed inactivity time after which the session will be terminated automatically. The default timeout is 1800 seconds.
Chapter 3 - Operation and Administration of the Macro BTS Using the Command Line Interface “Configuring the Session Timeout” on page 96 “Restoring the Default Value of the Session Timeout” on page 97 Command Syntax npu(config)# line {console | vty} Privilege Level 10 Syntax Description Parameter Description Presence Default Value Possible Values console | vty The terminal running the session to be managed: Mandatory N/A console Select console if you are connected via the MON port.
Chapter 3 - Operation and Administration of the Macro BTS Syntax Description Command Modes 3.1.8.2.3 Using the Command Line Interface Parameter Description Presence Default Value Possible Values The session timeout, in seconds.
Chapter 3 - Operation and Administration of the Macro BTS Syntax Description Using the Command Line Interface Parameter Description Presence Default Value Possible Values console | vty The session for which the timeout should be displayed: Mandatory N/A console console: a session via the MON port (even if there is currently no active session via the MON port). vty #: An active Telnet/SSH session number #. vty #, where # is the number of a currently active Telnet/SSH session.
Chapter 3 - Operation and Administration of the Macro BTS 3.2 Managing Software Upgrade Managing Software Upgrade This section includes: “Before You Start” on page 99 “Upgrading the NPU” on page 99 “Upgrading the AU” on page 106 3.2.1 Before You Start To load new NPU/AU software files to the unit's flash memory, you are required to execute a simple loading procedure using a TFTP application.
Chapter 3 - Operation and Administration of the Macro BTS Managing Software Upgrade NOTE The operational image is the default image used for rebooting the NPU after system reset. The shadow image is the downloaded image that you can use to boot up the NPU. However, the next time the system is reset, it is the operational image that is used to boot up the NPU. 3.2.2.
