Table 2.3: WiMAX Forum working groups. As of July 2006, the Forum website also indicates the Global Roaming Working Group (GRWG)
Table 2.4: WiMAX Forum (http://www.wimaxforum.org) White Papers, last update: July 2006. Table was drawn with the help of Ziad Noun
Table 2.5: WiMAX products and networks timetable: (e), expected
Chapter 3: Protocol Layers and Topologies
Table 3.1: The five PHYsical interfaces defined in the 802.16 standard. (From IEEE Std 802.16e-2005 . Copyright IEEE 2006, IEEE. All rights reserved.)
Chapter 4: Frequency Utilisation and System Profiles
Table 4.1: License-exempt band channels. Current applicable regulations do not allow this standard to be operated in the CEPT band B. (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved.)
Table 4.2: Transmit spectral mask parameters . A, B, C and D are in MHz
Table 4.3: Expected WiMAX frequencies (based on RWG documents)
Table 4.4: Fixed WiMAX certification profiles, all using the OFDM PHY and the PMP modes
Table 4.5: Release 1 Mobile WiMAX certification profiles, all using the OFDMA PHY and the PMP modes
Chapter 5: Digital Modulation, OFDM and OFDMA
Table 5.1: Possible phase values for QPSK modulation
Table 5.2: OFDM PHY data rates in Mb/s. (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved.)
Table 5.3: Example of SOFDMA figures. (Inspired from Reference .)
Table 5.4: The number of subchannels and the subcarrier indices used for each (five bits) subchannel index. (Based on Reference .)
Table 5.5: Slot definition
Table 5.6: Numerical parameters of the downlink PUSC example
Table 5.7: Downlink PUSC clusters major groups (1024-FFT OFDMA)
Table 5.8: Correspondence between subchannels and major groups. (Based on Reference .)
Table 5.9: Original cluster numbering (major group 3)
Table 5.10: Subcarrier allocation
Table 5.11: Pilot subcarrier physical index
Table 5.12: Instantaneous data rate of one subchannel. (unit: kb/s)
Chapter 6: The Physical Layer of WiMAX
Table 6.1: BTC component codes of OFDM PHY. (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved)
Table 6.2: Downlink burst profile parameters for OFDM and OFDMA PHYsical layers
Table 6.3: Uplink burst profile parameters for the OFDMA PHYsical Layer
Table 6.4: Uplink burst profile parameters for the OFDMA PHYsical Layer
Table 6.5: Received SNR threshold assumptions , Table 266. (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved.)
Chapter 7: Convergence Sublayer (CS)
Table 7.1: CID ranges as defined in Reference . Values are between 0000 (the 16 bits are equal to zero) and FFFF (the 16 bits are equal to one). It seems probable that the BS decides for a number m of CIDs for each of the basic and primary management connections that may be requested, i.e. a total of 2m connections. The CID value of basic, primary and secondary management connections for each SS are assigned in a ranging message (see Chapter 11). (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved.)
Table 7.2: Possible values of the PHS support field
Chapter 8: MAC Functions and MAC Frames
Table 8.1: Some fields of the MAC frame generic header. (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved.)
Table 8.2: Encoding of the bits of the type field in the generic MAC header. (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved.)
Table 8.4: Header format without payload Type I use. (Based on Reference .)
Table 8.3: Some fields of the MAC header without payload Type 1. (Based on Reference .)
Table 8.5: List of all 802. 16-2004 MAC management messages. See Annex A for brief descriptions of each message. (From IEEE Std 802. 16-2004 . Copyright IEEE 2004, IEEE. All rights reserved.)
Table 8.6: MAC management messages added by the 802.16e amendment. (From IEEE Std 802.16e-2005 . Copyright IEEE 2006, IEEE. All rights reserved.)
Table 8.7: Brief descriptions of TLV encoding sets in the 802.16 standard. Several Type values are common to different sets but no confusion is possible
Table 8.8: ARQ Feedback Information Element (IE) contents (the list is nonexhaustive). (From IEEE Std 802.16-2004 . Copyright IEEE 2004, IEEE. All rights reserved)
Chapter 9: Multiple Access and Burst Profile Description
Table 9.1: Frame duration possible values for OFDM (WiMAX) PHY Interface (based on .)
Table 9.2: OFDMA DL-MAP IE main parameters
Table 9.3: Format of the downlink burst profile for the OFDM (WiMAX) profile
Table 9.4: Some parameters of an OFDM PHY burst profile: FEC and modulation possible values. the corresponding mandatory CINR thresholds values (see Chapter 6 for burst profile parameters)
Table 9.5: Example of a DCD message containing two burst profile descriptions (OFDM PHY. 802.16e modifications not included). The full details are given in Annex B
Table 9.6: The possible values of DIUC (coded on 4 bits) for OFDM PHYsical Layer. Only 11 values are used for burst profile selection
Table 9.7: Extended DIUC possible uses for the OFDM PHYsical Layer
Table 9.8: The possible values of DIUC for the OFDMA PHYsical Layer
Table 9.9: The possible values of the UIUC (coded on 4 bits) for OFDM PHY
Chapter 10: Uplink Bandwidth Allocation and Request Mechanisms
Table 10.1: Example of UL-MAP message contents. Two UL-MAP_IE fields, subchannel index and midamble repetition interval are not shown in this table
Table 10.2: The steps of the focused contention (REQ Region Focused) procedure
Table 10.3: Summary of OFDM PHY contention-based uplink grant-request methods
Chapter 11: Network Entry and Quality of Service (QoS) Management
Table 11.1: RNG-REQ message paramters. Some of these fields are TLV coded
Table 11.2: Some of the parameters of the RNG-RSP message. Some of these fields are TLV coded
Table 11.3: Mandatory QoS parameters of the scheduling services defined in 802.16-2004. If present, the minimum reserved traffic rate parameter of the UGS must have the same value as the maximum sustained traffic rate parameter
Table 11.4: Poll/grant options for each scheduling service
Table 11.5: Scheduling service type (or QoS class) for some services.
Chapter 12: Efficient Use of Radio Resources
Table 12.1: Normalised C/N values for power control procedures for OFDMA-based WiMAX terminals. (From IEEE Std 802.16e–2005 . Copyright IEEE 2006, IEEE. All rights reserved.)
Chapter 13: WiMAX Architecture
Table 13.1: WiMAX service definition. (Based on Reference .)
Table 13.2: Split of ASN functions between BS and ASN-GW for profile A and profile C ASN. Based on Reference .)
Table 13.3: PoA IP address method according to the WiMAX access services and IP version
Chapter 15: Security
Table 15.1: Encryption keys used in the 802.16 standard, in its 802.16-2004 version, i.e. PKMvl. (Table by L. Rouill&eU and X. Lagrange at ENST Bretagne.)
Table 15.2: The main keys used in the 802.16 standard after the 802.16e amendment. (Table by L. Nuaymi, M. Boutin and M. Jubin.)
Table 15.3: The main differences between PKMv1 and PKMv2. (Table by L. Nuaymi, M. Boutin and M. Jubin.)
Table 15.4: PKM MAC mangement message parameters and descriptions. The Core Code Field in a KM-XXX message indicates its type. (Table by L. Rouill and X. Lagrange at ENST Bretagne.)
Chapter 16: Comparisons and Conclusion
Table 16.1: Some comparison points between WiFi WLAN and WiMAX BWA
Table 16.2: Some comparison elements between major wireless systems