User's Manual
Table Of Contents
- System Manual BreezeMAX Extreme
- About This Manual
- Contents
- Chapter 1 - System Description
- 1.1 About WiMAX
- 1.2 WiMAX Network Architecture
- 1.3 BreezeMAX Extreme
- 1.4 Specifications
- 1.4.1 General Modem and Radio
- 1.4.2 3.x GHz BTS
- 1.4.3 5 GHz BTS
- 1.4.4 Sensitivity
- 1.4.5 3.x GHz Antennas
- 1.4.6 5 GHz Antennas
- 1.4.7 Power Supply
- 1.4.8 GPS Antennas
- 1.4.9 Data Communication (Ethernet Port)
- 1.4.10 Configuration and Management
- 1.4.11 Environmental
- 1.4.12 BTS Standards Compliance, General
- 1.4.13 Notes on Maximum Tx Power Limitations for 5 GHz Units Using FCC Country Code:
- 1.4.14 TDWR Interference Avoidance
- Chapter 2 - Installation
- 2.1 Site Deployment Options
- 2.2 BTS Installation
- 2.3 GPS Installation
- 2.4 Indoor Power Supply Installation
- 2.5 Cable Connections
- 2.6 External Antennas Connection
- Chapter 3 - Commissioning
- Chapter 4 - Operation and Administration
- 4.1 BreezeMAX Extreme System Management
- 4.2 The Monitor Program
- 4.3 IP Addresses Configuration
- 4.4 The Main Menu
- 4.5 BTS Menu
- 4.5.1 Show Summary
- 4.5.2 Show Properties
- 4.5.3 Show License Properties
- 4.5.4 Configuration
- 4.5.5 Unit Control
- 4.5.6 Fault Management
- 4.5.7 Performance Counters
- 4.6 ASN-GW Menu
- 4.6.1 AAA
- 4.6.2 Services Menu
- 4.6.2.1 Introduction
- 4.6.2.2 Common Operations in Services Menus
- 4.6.2.3 MSs Services
- 4.6.2.4 Service Profiles
- 4.6.2.5 QoS Profiles
- 4.6.2.6 Multiple Service Flows
- 4.6.2.7 Service Rules
- 4.6.2.8 Classifiers
- 4.6.2.9 Service Groups
- 4.6.2.9.1 Service Group ID
- 4.6.2.9.2 Service Group Name
- 4.6.2.9.3 DHCP Type
- 4.6.2.9.4 Nomadic Mode
- 4.6.2.9.5 Attribute 31
- 4.6.2.9.6 Attribute 32
- 4.6.2.9.7 Attribute 32 Free Text
- 4.6.2.9.8 Interface IP Address
- 4.6.2.9.9 Interface Subnet Mask
- 4.6.2.9.10 Default Gateway
- 4.6.2.9.11 VLAN ID
- 4.6.2.9.12 VLAN Priority
- 4.6.2.9.13 DHCP Server Specific Parameters
- 4.6.2.9.14 Option 82 Parameters
- 4.6.2.9.15 DHCP Relay with Option 82 Specific Parameters
- 4.6.2.9.16 Show DHCP Lease Times
- 4.6.2.10 Service Interfaces
- 4.6.2.10.1 Service Interface ID
- 4.6.2.10.2 Service Interface Name
- 4.6.2.10.3 Forwarding Rule Name
- 4.6.2.10.4 CS Type
- 4.6.2.10.5 VLAN Interface
- 4.6.2.10.6 VLAN Transparency
- 4.6.2.10.7 VLAN ID
- 4.6.2.10.8 VLAN Priority Marking
- 4.6.2.10.9 VLAN Priority
- 4.6.2.10.10 VLAN List
- 4.6.2.10.11 Inner DSCP Marking
- 4.6.2.10.12 Inner DSCP
- 4.6.2.11 Forwarding Rules
- 4.6.2.12 MSs Default Services
- 4.6.3 MAC Access Lists
- 4.7 Sector Menu
- 4.8 BS Menu
- 4.9 Radio Channel Menu
- 4.10 Antenna Menu
- 4.11 GPS Menu
- 4.12 MS Menu
- 4.13 Parameters Summary
- Glossary
Chapter 4 - Operation and Administration ASN-GW Menu
BreezeMAX Extreme 133 System Manual
HARQ Repetitions (Read-only)
4.6.2.4.1 Service Profile ID
This is an auto-sequential number from 1 to a maximum of 64, generated
automatically during creation of a new Service Profile.
4.6.2.4.2 Service Profile Name
The Name of the Service Profile. A unique string of 1 to 32 characters.
4.6.2.4.3 Service Profile Type
The type of a service using the Service Profile. The options available in the current
release are:
Management
Data
PPPoE
VoIP
Reliable Video (decreases dropped packets rate)
Optimized Video (wireless link optimization with content awareness)
4.6.2.4.4 HARQ Repetitions
HARQ (Hybrid-ARQ) is an ARQ (Automatic Repeat reQuest) mechanism that is
implemented at the physical layer together with FEC, providing improved link
performance over traditional ARQ at the cost of increased implementation
complexity. HARQ uses a combination of FEC and ARQ, where blocks of data,
along with a CRC code, are encoded using a FEC coder before transmission;
retransmission is requested if the decoder is unable to correctly decode the
received block. When a retransmitted coded block is received, it is combined with
the previously detected coded block and fed to the input of the FEC decoder.
Combining the two or more received versions of the code block improves the
chances of correctly decoding.
The WiMAX standard supports this by combining an N-channel stop and wait
ARQ along with a variety of supported FEC codes. Doing multiple parallel
channels of HARQ at a time can improve the throughput, since when one HARQ
process is waiting for an acknowledgment, another process can use the channel to
send some more data. WiMAX supports signaling mechanisms to allow
asynchronous operation of HARQ and supports a dedicated acknowledgment