/* msg_sbc.c
 * WiMax MAC Management SBC-REQ/RSP Messages decoders
 *
 * Copyright (c) 2007 by Intel Corporation.
 *
 * Author: Lu Pan <lu.pan@intel.com>
 *
 * $Id$
 *
 * Wireshark - Network traffic analyzer
 * By Gerald Combs <gerald@wireshark.org>
 * Copyright 1999 Gerald Combs
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.
 */

/*
#define DEBUG	// for debug only
*/

/* Include files */

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include <glib.h>
#include <epan/packet.h>
#include "wimax_tlv.h"
#include "wimax_mac.h"
#include "wimax_utils.h"

/* This is a global variable declared in mac_hd_generic_decoder.c, which determines whether
 *    or not cor2 changes are included */
extern guint include_cor2_changes;

static gint proto_mac_mgmt_msg_sbc_decoder = -1;
static gint ett_mac_mgmt_msg_sbc_decoder = -1;
static gint ett_sbc_req_tlv_subtree = -1;
static gint ett_sbc_rsp_tlv_subtree = -1;

/* fix fields */
static gint hf_sbc_req_message_type = -1;
static gint hf_sbc_rsp_message_type = -1;
static gint hf_sbc_unknown_type = -1;

static gint hf_sbc_bw_alloc_support = -1;
static gint hf_sbc_bw_alloc_support_rsvd0 = -1;
static gint hf_sbc_bw_alloc_support_duplex = -1;
static gint hf_sbc_bw_alloc_support_rsvd1 = -1;
static gint hf_sbc_curr_transmit_power = -1;
static gint hf_sbc_transition_gaps = -1;
static gint hf_sbc_ssttg = -1;
static gint hf_sbc_ssrtg = -1;
static gint hf_sbc_mac_pdu = -1;
static gint hf_sbc_mac_pdu_piggybacked = -1;
static gint hf_sbc_mac_pdu_fsn = -1;
static gint hf_sbc_mac_pdu_rsvd = -1;
static gint hf_sbc_max_transmit_power = -1;
static gint hf_sbc_ss_fft_sizes = -1;
static gint hf_sbc_ss_fft_256 = -1;
static gint hf_sbc_ss_fft_2048 = -1;
static gint hf_sbc_ss_fft_128 = -1;
static gint hf_sbc_ss_fft_512 = -1;
static gint hf_sbc_ss_fft_1024 = -1;
static gint hf_sbc_ss_cinr_measure_capability = -1;
static gint hf_sbc_ss_phy_cinr_measurement_preamble = -1;
static gint hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_pilot_subcarriers = -1;
static gint hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_data_subcarriers = -1;
static gint hf_sbc_ss_effective_cinr_measurement_preamble = -1;
static gint hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_pilot_subcarriers = -1;
static gint hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_data_subcarriers = -1;
static gint hf_sbc_ss_support_2_concurrent_cqi_channels = -1;
static gint hf_sbc_ss_frequency_selectivity_characterization_report = -1;

static gint hf_sbc_ss_fft_rsvd1 = -1;
static gint hf_sbc_ss_fft_rsvd2 = -1;
static gint hf_sbc_ss_demodulator = -1;
static gint hf_sbc_ss_demodulator_64qam = -1;
static gint hf_sbc_ss_demodulator_btc = -1;
static gint hf_sbc_ss_demodulator_ctc = -1;
static gint hf_sbc_ss_demodulator_stc = -1;
static gint hf_sbc_ss_demodulator_cc_with_optional_interleaver = -1;
static gint hf_sbc_ss_demodulator_harq_chase = -1;
static gint hf_sbc_ss_demodulator_harq_ctc_ir = -1;
static gint hf_sbc_ss_demodulator_reserved = -1;
static gint hf_sbc_ss_demodulator_reserved1 = -1;
static gint hf_sbc_ss_demodulator_64qam_2 = -1;
static gint hf_sbc_ss_demodulator_btc_2 = -1;
static gint hf_sbc_ss_demodulator_ctc_2 = -1;
static gint hf_sbc_ss_demodulator_stc_2 = -1;
static gint hf_sbc_ss_demodulator_cc_with_optional_interleaver_2 = -1;
static gint hf_sbc_ss_demodulator_harq_chase_2 = -1;
static gint hf_sbc_ss_demodulator_harq_ctc_ir_2 = -1;
static gint hf_sbc_ss_demodulator_reserved_2 = -1;
static gint hf_sbc_ss_demodulator_harq_cc_ir_2 = -1;
static gint hf_sbc_ss_demodulator_ldpc_2 = -1;
static gint hf_sbc_ss_demodulator_dedicated_pilots_2 = -1;
static gint hf_sbc_ss_demodulator_reserved1_2 = -1;

static gint hf_sbc_ss_modulator = -1;
static gint hf_sbc_ss_modulator_64qam = -1;
static gint hf_sbc_ss_modulator_btc = -1;
static gint hf_sbc_ss_modulator_ctc = -1;
static gint hf_sbc_ss_modulator_stc = -1;
static gint hf_sbc_ss_modulator_harq_chase = -1;
static gint hf_sbc_ss_modulator_ctc_ir = -1;
static gint hf_sbc_ss_modulator_cc_ir = -1;
static gint hf_sbc_ss_modulator_ldpc = -1;

static gint hf_sbc_number_ul_arq_ack_channel = -1;
static gint hf_sbc_number_dl_arq_ack_channel = -1;
static gint hf_sbc_ss_permutation_support = -1;
static gint hf_sbc_ss_optimal_pusc = -1;
static gint hf_sbc_ss_optimal_fusc = -1;
static gint hf_sbc_ss_amc_1x6 = -1;
static gint hf_sbc_ss_amc_2x3 = -1;
static gint hf_sbc_ss_amc_3x2 = -1;
static gint hf_sbc_ss_amc_with_harq_map = -1;
static gint hf_sbc_ss_tusc1_support = -1;
static gint hf_sbc_ss_tusc2_support = -1;
static gint hf_sbc_ss_ofdma_aas_private = -1;
static gint hf_sbc_ofdma_aas_harq_map_capability = -1;
static gint hf_sbc_ofdma_aas_private_map_support = -1;
static gint hf_sbc_ofdma_aas_reduced_private_map_support = -1;
static gint hf_sbc_ofdma_aas_private_chain_enable = -1;
static gint hf_sbc_ofdma_aas_private_map_dl_frame_offset = -1;
static gint hf_sbc_ofdma_aas_private_ul_frame_offset = -1;
static gint hf_sbc_ofdma_aas_private_map_concurrency = -1;
static gint hf_sbc_ofdma_aas_capabilities = -1;
static gint hf_sbc_ss_ofdma_aas_zone = -1;
static gint hf_sbc_ss_ofdma_aas_diversity_map_scan = -1;
static gint hf_sbc_ss_ofdma_aas_fbck_rsp_support = -1;
static gint hf_sbc_ss_ofdma_downlink_aas_preamble = -1;
static gint hf_sbc_ss_ofdma_uplink_aas_preamble = -1;
static gint hf_sbc_ss_ofdma_aas_capabilities_rsvd = -1;

static gint hf_sbc_tlv_t_167_association_type_support = -1;
static gint hf_sbc_tlv_t_167_association_type_support_bit0 = -1;
static gint hf_sbc_tlv_t_167_association_type_support_bit1 = -1;
static gint hf_sbc_tlv_t_167_association_type_support_bit2 = -1;
static gint hf_sbc_tlv_t_167_association_type_support_bit3  = -1;
static gint hf_sbc_tlv_t_167_association_type_support_bit4 = -1;
static gint hf_sbc_tlv_t_167_association_type_support_reserved = -1;
static gint hf_sbc_ofdma_ss_uplink_power_control_support = -1;
static gint hf_sbc_ofdma_ss_uplink_power_control_support_open_loop = -1;
static gint hf_sbc_ofdma_ss_uplink_power_control_support_aas_preamble = -1;
static gint hf_sbc_ofdma_ss_uplink_power_control_support_rsvd = -1;
static gint hf_sbc_ofdm_ss_minimum_num_of_frames = -1;
static gint hf_sbc_tlv_t_27_extension_capability = -1;
static gint hf_sbc_tlv_t_27_extension_capability_bit0 = -1;
static gint hf_sbc_tlv_t_27_extension_capability_reserved = -1;
static gint hf_sbc_tlv_t_28_ho_trigger_metric_support = -1;
static gint hf_sbc_tlv_t_28_ho_trigger_metric_support_bit0 = -1;
static gint hf_sbc_tlv_t_28_ho_trigger_metric_support_bit1 = -1;
static gint hf_sbc_tlv_t_28_ho_trigger_metric_support_bit2 = -1;
static gint hf_sbc_tlv_t_28_ho_trigger_metric_support_bit3 = -1;
static gint hf_sbc_tlv_t_28_ho_trigger_metric_support_reserved = -1;
static gint hf_sbc_tlv_t_171_minimum_num_of_frames = -1;
static gint hf_sbc_tlv_t_172_harq_map_capability = -1;
static gint hf_sbc_tlv_t_172_extended_harq_ie_capability = -1;
static gint hf_sbc_tlv_t_172_sub_map_capability_first_zone = -1;
static gint hf_sbc_tlv_t_172_sub_map_capability_other_zones = -1;
static gint hf_sbc_tlv_t_172_dl_region_definition_support = -1;
static gint hf_sbc_tlv_t_172_reserved = -1;
static gint hf_sbc_tlv_t_172 = -1;
static gint hf_sbc_tlv_t_173_ul_ctl_channel_support = -1;
static gint hf_sbc_tlv_t_173_3_bit_mimo_fast_feedback = -1;
static gint hf_sbc_tlv_t_173_enhanced_fast_feedback = -1;
static gint hf_sbc_tlv_t_173_ul_ack = -1;
static gint hf_sbc_tlv_t_173_reserved = -1;
static gint hf_sbc_tlv_t_173_uep_fast_feedback = -1;
static gint hf_sbc_tlv_t_173_measurement_report = -1;
static gint hf_sbc_tlv_t_173_primary_secondary_fast_feedback = -1;
static gint hf_sbc_tlv_t_173_diuc_cqi_fast_feedback = -1;
static gint hf_sbc_tlv_t_174_ofdma_ms_csit_capability = -1;
static gint hf_sbc_tlv_t_174_csit_compatibility_type_a = -1;
static gint hf_sbc_tlv_t_174_csit_compatibility_type_b = -1;
static gint hf_sbc_tlv_t_174_power_assignment_capability = -1;
static gint hf_sbc_tlv_t_174_sounding_rsp_time_capability = -1;
static gint hf_sbc_tlv_t_174_max_num_simultanous_sounding_instructions = -1;
static gint hf_sbc_tlv_t_174_ss_csit_type_a_support  = -1;
static gint hf_sbc_tlv_t_204_ofdma_parameters_sets = -1;
static gint hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_a = -1;
static gint hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_b = -1;
static gint hf_sbc_tlv_t_204_ofdma_parameters_sets_harq_parameters_set = -1;
static gint hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_a = -1;
static gint hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_b = -1;
static gint hf_sbc_tlv_t_204_ofdma_parameters_sets_reserved = -1;
static gint hf_sbc_tlv_t_174_ss_csit_reserved  = -1;
static gint hf_sbc_tlv_t_175_max_num_bst_per_frm_capability_harq = -1;
static gint hf_sbc_tlv_t_175_max_num_ul_harq_bst = -1;
static gint hf_sbc_tlv_t_175_max_num_ul_harq_per_frm_include_one_non_harq_bst = -1;
static gint hf_sbc_tlv_t_175_max_num_dl_harq_bst_per_harq_per_frm = -1;
static gint hf_sbc_tlv_t_176 = -1;
static gint hf_sbc_tlv_t_176_bit0 = -1;
static gint hf_sbc_tlv_t_176_bit1 = -1;
static gint hf_sbc_tlv_t_176_bit2 = -1;
static gint hf_sbc_tlv_t_176_bit2_cor2 = -1;
static gint hf_sbc_tlv_t_176_bit3 = -1;
static gint hf_sbc_tlv_t_176_bit4 = -1;
static gint hf_sbc_tlv_t_176_bit5 = -1;
static gint hf_sbc_tlv_t_176_bit6 = -1;
static gint hf_sbc_tlv_t_176_bit7 = -1;
static gint hf_sbc_tlv_t_176_bit8 = -1;
static gint hf_sbc_tlv_t_176_bit9 = -1;
static gint hf_sbc_tlv_t_176_bit10 = -1;
static gint hf_sbc_tlv_t_176_bit11 = -1;
static gint hf_sbc_tlv_t_176_bit12 = -1;
static gint hf_sbc_tlv_t_176_bit13 = -1;
static gint hf_sbc_tlv_t_176_bit14 = -1;
static gint hf_sbc_tlv_t_176_bit15 = -1;
static gint hf_sbc_tlv_t_176_bit16 = -1;
static gint hf_sbc_tlv_t_176_bit17 = -1;
static gint hf_sbc_tlv_t_176_bit18 = -1;
static gint hf_sbc_tlv_t_176_bit19 = -1;
static gint hf_sbc_tlv_t_176_reserved = -1;
static gint hf_sbc_tlv_t_177_ofdma_ss_modulator_for_mimo_support = -1;
static gint hf_sbc_tlv_t_177_stc_matrix_a = -1;
static gint hf_sbc_tlv_t_177_stc_matrix_b_vertical = -1;
static gint hf_sbc_tlv_t_177_stc_matrix_b_horizontal = -1;
static gint hf_sbc_tlv_t_177_two_transmit_antennas = -1;
static gint hf_sbc_tlv_t_177_capable_of_transmit_diversity = -1;
static gint hf_sbc_tlv_t_177_capable_of_spacial_multiplexing = -1;
static gint hf_sbc_tlv_t_177_beamforming = -1;
static gint hf_sbc_tlv_t_177_adaptive_rate_ctl = -1;
static gint hf_sbc_tlv_t_177_single_antenna = -1;
static gint hf_sbc_tlv_t_177_collaborative_sm_with_one_antenna = -1;
static gint hf_sbc_tlv_t_177_collaborative_sm_with_two_antennas = -1;
static gint hf_sbc_tlv_t_177_capable_of_two_antenna = -1;
static gint hf_sbc_tlv_t_177_rsvd = -1;
static gint hf_sbc_tlv_t_178_sdma_pilot_capability = -1;
static gint hf_sbc_tlv_t_178_sdma_pilot_pattern_support_for_amc_zone = -1;
static gint hf_sbc_tlv_t_178_reserved = -1;
static gint hf_sbc_tlv_t_179_ofdma_multiple_dl_burst_profile_support = -1;
static gint hf_sbc_tlv_t_179_dl_bst_profile_for_multiple_fec = -1;
static gint hf_sbc_tlv_t_179_ul_bst_profile_for_multiple_fec = -1;
static gint hf_sbc_tlv_t_179_reserved = -1;
static gint hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability = -1;
static gint hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_NEP = -1;
static gint hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_dl = -1;
static gint hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_ul = -1;
static gint hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved1 = -1;
static gint hf_sbc_tlv_t_162_ul_harq_incremental_redundancy_buffer_capability_NEP = -1;
static gint hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved2 = -1;
static gint hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability = -1;
static gint hf_sbc_tlv_t_163_dl_harq_buffering_capability_for_chase_combining = -1;
static gint hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_dl = -1;
static gint hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved1 = -1;
static gint hf_sbc_tlv_t_163_ul_harq_buffering_capability_for_chase_combining = -1;
static gint hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_ul = -1;
static gint hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved2 = -1;

static gint hf_sbc_ss_demodulator_mimo_support = -1;
static gint hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_a = -1;
static gint hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_vertical = -1;
static gint hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_horizontal = -1;
static gint hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_a = -1;
static gint hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_vertical = -1;
static gint hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_horizontal = -1;
static gint hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_vertical = -1;
static gint hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_horizontal = -1;
static gint hf_sbc_ss_demodulator_mimo_rsvd = -1;
static gint hf_sbc_ss_mimo_uplink_support = -1;
static gint hf_sbc_ss_mimo_uplink_support_2_ann_sttd = -1;
static gint hf_sbc_ss_mimo_uplink_support_2_ann_sm_vertical = -1;
static gint hf_sbc_ss_mimo_uplink_support_1_ann_coop_sm = -1;
static gint hf_sbc_ss_mimo_uplink_support_rsvd = -1;

static gint hf_sbc_power_save_class_types_capability = -1;
static gint hf_sbc_power_save_class_types_capability_bit0 = -1;
static gint hf_sbc_power_save_class_types_capability_bit1 = -1;
static gint hf_sbc_power_save_class_types_capability_bit2 = -1;
static gint hf_sbc_power_save_class_types_capability_bits34 = -1;
static gint hf_sbc_power_save_class_types_capability_bits567 = -1;

static gint hf_sbc_pkm_flow_control = -1;
static gint hf_sbc_auth_policy = -1;
static gint hf_sbc_privacy_802_16 = -1;
static gint hf_sbc_privacy_rsvd = -1;
static gint hf_sbc_max_security_associations = -1;

static gint hf_sbc_invalid_tlv = -1;

static const true_false_string tfs_sbc_bw_alloc_support_duplex =
{
    "Full-Duplex",
    "Half-Duplex"
};

static const value_string vals_sbc_mac_pdu_fsn[] =
{
    {0, "Only 11-bit FSN values are supported"},
    {1, "Only 3-bit FSN values are supported"},
    {0,  NULL}
};
static const true_false_string tfs_sbc_mac_pdu_fsn =
{
    "Only 3-bit FSN values are supported",
    "Only 11-bit FSN values are supported"
};

/* DCD DIUC messages (table 143) */
static const value_string diuc_msgs[] =
{
    { 0, "Downlink Burst Profile 1" },
    { 1, "Downlink Burst Profile 2" },
    { 2, "Downlink Burst Profile 3" },
    { 3, "Downlink Burst Profile 4" },
    { 4, "Downlink Burst Profile 5" },
    { 5, "Downlink Burst Profile 6" },
    { 6, "Downlink Burst Profile 7" },
    { 7, "Downlink Burst Profile 8" },
    { 8, "Downlink Burst Profile 9" },
    { 9, "Downlink Burst Profile 10" },
    { 10, "Downlink Burst Profile 11" },
    { 11, "Downlink Burst Profile 12" },
    { 12, "Downlink Burst Profile 13" },
    { 13, "Reserved" },
    { 14, "Gap" },
    { 15, "End of DL-MAP" },
    {0,   NULL}
};

static const value_string vals_sbc_type[] =
{
    {0, "CINR metric"},
    {1, "RSSI metric"},
    {2, "RTD metric"},
    {3, "Reserved"},
    {0,  NULL}
};

static const value_string vals_sbc_function[] =
{
    {0, "Reserved"},
    {1, "Metric of neighbor BS is greater than absolute value"},
    {2, "Metric of neighbor BS is less than absolute value"},
    {3, "Metric of neighbor BS is greater than serving BS metric by relative value"},
    {4, "Metric of neighbor BS is less than serving BS metric by relative value"},
    {5, "Metric of serving BS greater than absolute value"},
    {6, "Metric of serving BS less than absolute value"},
    {7, "Reserved"},
    {0,  NULL}
};

static const value_string vals_sbc_action[] =
{
    {0, "Reserved"},
    {1, "Respond on trigger with MOB_SCN-REP after the end of each scanning interval"},
    {2, "Respond on trigger with MOB_MSH-REQ"},
    {3, "On trigger, MS starts neighbor BS scanning process by sending MOB_SCN-REQ"},
    {4, "Reserved"},
    {0,  NULL}
};

static const value_string vals_sbc_power_adjustmnt[] =
{
    {0, "Preserve Peak Power"},
    {1, "Preserve Mean Power"},
    {0,  NULL}
};

static const true_false_string tfs_sbc_power_adjustment =
{
    "Preserve Mean Power",
    "Preserve Peak Power"
};

static const value_string vals_reg_rsp_status[] =
{
    {0, "OK"},
    {1, "Message authentication failure"},
    {0,  NULL}
};

static const value_string vals_sbc_burst_tcs[] =
{
    {0, "TCS disabled"},
    {1, "TCS enabled"},
    {0,  NULL}
};

static const true_false_string tfs_sbc_burst_tcs =
{
    "TCS enabled",
    "TCS disabled"
};

static const value_string vals_sbc_frame_duration[] =
{
    {0, "2.5"},
    {1, "4"},
    {2, "5"},
    {3, "8"},
    {4, "10"},
    {5, "12.5"},
    {6, "20"},
    {0,  NULL}
};

static const value_string vals_sbc_mac_version[] =
{
    {1, "Conformance with IEEE Std 802.16-2001"},
    {2, "Conformance with IEEE Std 802.16c-2002 and its predecessors"},
    {3, "Conformance with IEEE Std 802.16a-2003 and its predecessors"},
    {4, "Conformance with IEEE Std 802.16-2004"},
    {5, "Conformance with IEEE Std 802.16-2004 and IEEE Std 802.16e-2005"},
    {6, "reserved"},
    {0, NULL}
};

static const value_string vals_sbc_burst_fec[] =
{
    {0, "QPSK (CC) 1/2"},
    {1, "QPSK (CC) 3/4"},
    {2, "16-QAM (CC) 1/2"},
    {3, "16-QAM (CC) 3/4"},
    {4, "64-QAM (CC) 1/2"},
    {5, "64-QAM (CC) 2/3"},
    {6, "64-QAM (CC) 3/4"},
    {7, "QPSK (BTC) 1/2"},
    {8, "QPSK (BTC) 3/4 or 2/3"},
    {9, "16-QAM (BTC) 3/5"},
    {10, "16-QAM (BTC) 4/5"},
    {11, "64-QAM (BTC) 2/3 or 5/8"},
    {12, "64-QAM (BTC) 5/6 or 4/5"},
    {13, "QPSK (CTC) 1/2"},
    {14, "Reserved"},
    {15, "QPSK (CTC) 3/4"},
    {16, "16-QAM (CTC) 1/2"},
    {17, "16-QAM (CTC) 3/4"},
    {18, "64-QAM (CTC) 1/2"},
    {19, "64-QAM (CTC) 2/3"},
    {20, "64-QAM (CTC) 3/4"},
    {21, "64-QAM (CTC) 5/6"},
    {22, "QPSK (ZT CC) 1/2"},
    {23, "QPSK (ZT CC) 3/4"},
    {24, "16-QAM (ZT CC) 1/2"},
    {25, "16-QAM (ZT CC) 3/4"},
    {26, "64-QAM (ZT CC) 1/2"},
    {27, "64-QAM (ZT CC) 2/3"},
    {28, "64-QAM (ZT CC) 3/4"},
    {29, "QPSK (LDPC) 1/2"},
    {30, "QPSK (LDPC) 2/3 A code"},
    {31, "16-QAM (LDPC) 3/4 A code"},
    {32, "16-QAM (LDPC) 1/2"},
    {33, "16-QAM (LDPC) 2/3 A code"},
    {34, "16-QAM (LDPC) 3/4 A code"},
    {35, "64-QAM (LDPC) 1/2"},
    {36, "64-QAM (LDPC) 2/3 A code"},
    {37, "64-QAM (LDPC) 3/4 A code"},
    {38, "QPSK (LDPC) 2/3 B code"},
    {39, "QPSK (LDPC) 3/4 B code"},
    {40, "16-QAM (LDPC) 2/3 B code"},
    {41, "16-QAM (LDPC) 3/4 B code"},
    {42, "64-QAM (LDPC) 2/3 B code"},
    {43, "64-QAM (LDPC) 3/4 B code"},
    {44, "QPSK (CC with optional interleaver) 1/2"},
    {45, "QPSK (CC with optional interleaver) 3/4"},
    {46, "16-QAM (CC with optional interleaver) 1/2"},
    {47, "16-QAM (CC optional interleaver) 0%00"},
    {48, "64-QAM (CC with optional interleaver) 2/3"},
    {49, "64-QAM (CC with optional interleaver) 3/4"},
    {50, "QPSK (LDPC) 5/6"},
    {51, "16-QAM (LDPC) 5/6"},
    {52, "64-QAM (LDPC) 5/6"},
    {0,  NULL}
};

static const value_string vals_sbc_permutation_type[] =
{
    {0, "PUSC" },
    {1, "FUSC" },
    {2, "optional FUSC"},
    {3, "AMC"},
    {0,  NULL}
};

static const value_string vals_sbc_harq_parameters_set[] =
{
    {0, "HARQ set 1"},
    {1, "HARQ set 2"},
    {2, "HARQ set 3"},
    {3, "HARQ set 4"},
    {4, "HARQ set 5"},
    {5, "Reserved"},
    {0, NULL}
};

static const true_false_string tfs_supported =
{
    "supported",
    "not supported"
};

static const true_false_string tfs_yes_no_sbc =
{
    "yes",
    "no"
};

static const value_string vals_sounding_rsp_time_cap_codings[] =
{
    {0, "0.5ms" },
    {1, "0.75ms" },
    {2, "1ms"},
    {3, "1.25ms"},
    {4, "1.5ms"},
    {5, "min(2, Next Frame)"},
    {6, "min(5, Next Frame)"},
    {7, "Next Frame"},
    {0,  NULL}
};

static const value_string vals_sbc_sdma_str[ ] =
{
    {0, "no support"},
    {1, "support SDMA pilot patterns #A and #B"},
    {2, "support all SDMA pilot patterns"},
    {3, "reserved"},
    {0,  NULL}
};


/* Wimax Mac SBC-REQ Message Dissector */
void dissect_mac_mgmt_msg_sbc_req_decoder(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
{
	guint offset = 0;
	guint tvb_len, payload_type, value;
	gint  tlv_type, tlv_len, tlv_value_offset;
	guint num_dl_harq_chans;
	proto_item *sbc_item = NULL;
	proto_tree *sbc_tree = NULL;
	proto_item *tlv_item = NULL;
	proto_tree *tlv_tree = NULL;
	proto_item *ti = NULL;
	tlv_info_t tlv_info;
	gfloat power_bpsk;
	gfloat power_qpsk;
	gfloat power_qam16;
	gfloat power_qam64;
	gfloat current_power;

	/* Ensure the right payload type */
	payload_type = tvb_get_guint8(tvb, offset);
	if (payload_type != MAC_MGMT_MSG_SBC_REQ)
	{
		return;
	}

	if (tree)
	{	/* we are being asked for details */
		/* Get the tvb reported length */
		tvb_len =  tvb_reported_length(tvb);
		/* display MAC payload type SBC-REQ */
		sbc_item = proto_tree_add_protocol_format(tree, proto_mac_mgmt_msg_sbc_decoder, tvb, offset, tvb_len, "SS Basic Capability Request (SBC-REQ) (%u bytes)", tvb_len);
		/* add MAC SBC subtree */
		sbc_tree = proto_item_add_subtree(sbc_item, ett_mac_mgmt_msg_sbc_decoder);
		/* Decode and display the SS Basic Capability Request (SBC-REQ) */
		/* display the Message Type */
		proto_tree_add_item(sbc_tree, hf_sbc_req_message_type, tvb, offset, 1, FALSE);
		/* set the offset for the TLV Encoded info */
		offset++;
		/* process the SBC TLVs */
		while(offset < tvb_len)
		{
			/* get the TLV information */
			init_tlv_info(&tlv_info, tvb, offset);
			/* get the TLV type */
			tlv_type = get_tlv_type(&tlv_info);
			/* get the TLV length */
			tlv_len = get_tlv_length(&tlv_info);
			if (tlv_type == -1 || tlv_len > MAX_TLV_LEN || tlv_len < 1)
			{	/* invalid tlv info */
				col_append_sep_str(pinfo->cinfo, COL_INFO, NULL, "SBC-REQ TLV error");
				proto_tree_add_item(sbc_tree, hf_sbc_invalid_tlv, tvb, offset, (tvb_len - offset), FALSE);
				break;
			}
			if (tlv_type == 0)
			{	/* invalid tlv type */
				col_append_sep_str(pinfo->cinfo, COL_INFO, NULL, "Invalid SBC TLV type");
				proto_tree_add_item(sbc_tree, hf_sbc_unknown_type, tvb, offset, 1, FALSE);
				offset++;
				continue;
			}
			/* get the TLV value offset */
			tlv_value_offset = get_tlv_value_offset(&tlv_info);
#ifdef DEBUG /* for debug only */
			proto_tree_add_protocol_format(sbc_tree, proto_mac_mgmt_msg_sbc_decoder, tvb, offset, (tlv_len + tlv_value_offset), "SBC-REQ Type: %u (%u bytes, offset=%u, tlv_len=%u, tvb_len=%u)", tlv_type, (tlv_len + tlv_value_offset), offset, tlv_len, tvb_len);
#endif
			/* update the offset for the TLV value */
			offset += tlv_value_offset;
			/* process SBC TLV Encoded information */
			switch (tlv_type)
			{
				case SBC_BW_ALLOC_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_bw_alloc_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_bw_alloc_support_rsvd0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_bw_alloc_support_duplex, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_bw_alloc_support_rsvd1, tvb, offset, 1, FALSE);
				break;
				case SBC_TRANSITION_GAPS:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_transition_gaps, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					ti = proto_tree_add_item(tlv_tree, hf_sbc_ssttg, tvb, offset, 1, FALSE);
					proto_item_append_text(ti, " us (ranges: TDD 0-50; H-FDD 0-100)");
					ti = proto_tree_add_item(tlv_tree, hf_sbc_ssrtg, tvb, (offset + 1), 1, FALSE);
					proto_item_append_text(ti, " us (ranges: TDD 0-50; H-FDD 0-100)");
				break;
				case SBC_MAC_PDU:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_mac_pdu, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_mac_pdu_piggybacked, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_mac_pdu_fsn, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_mac_pdu_rsvd, tvb, offset, 1, FALSE);
				break;
				case SBC_REQ_MAX_TRANSMIT_POWER: /* TODO: This TLV comes up as INVALID in wireshark... why? */
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_max_transmit_power, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					power_bpsk = (gfloat)(tvb_get_guint8(tvb, offset) - 128) / 2;
					power_qpsk = (gfloat)(tvb_get_guint8(tvb, (offset + 1)) - 128) / 2;
					power_qam16 = (gfloat)(tvb_get_guint8(tvb, (offset + 2)) - 128) / 2;
					power_qam64 = (gfloat)(tvb_get_guint8(tvb, (offset + 3)) - 128) / 2;
					proto_tree_add_text(tlv_tree, tvb, offset, 1, "BPSK: %.2f dBm", (gdouble)power_bpsk);
					proto_tree_add_text(tlv_tree, tvb, (offset + 1), 1, "QPSK: %.2f dBm", (gdouble)power_qpsk);
					proto_tree_add_text(tlv_tree, tvb, (offset + 2), 1, "QAM16: %.2f dBm", (gdouble)power_qam16);
					proto_tree_add_text(tlv_tree, tvb, (offset + 3), 1, "QAM64: %.2f dBm", (gdouble)power_qam64);
				break;
				case SBC_REQ_CURR_TRANSMITTED_POWER:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_curr_transmit_power, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					value = tvb_get_guint8(tvb, offset);
					current_power = (gfloat)(value - 128) / 2;
					proto_tree_add_text(tlv_tree, tvb, offset, 1, "Current Transmitted Power: %.2f dBm (Value: 0x%x)", (gdouble)current_power, value);
				break;
				case SBC_SS_FFT_SIZES:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_fft_sizes, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					if (include_cor2_changes)
					{
						proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_rsvd1, tvb, offset, 1, FALSE);
					} else {
						proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_256, tvb, offset, 1, FALSE);
					}
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_2048, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_128, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_512, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_1024, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_rsvd2, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_DEMODULATOR:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_demodulator, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					if (tlv_len == 1) /* && (num_dl_harq_chans < 8)) */
					{
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_64qam, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_btc, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_ctc, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_stc, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_cc_with_optional_interleaver, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_chase, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_ctc_ir, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_reserved, tvb, offset, 1, FALSE);
					}
					else
					{
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_64qam_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_btc_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_ctc_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_stc_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_cc_with_optional_interleaver_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_chase_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_ctc_ir_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_reserved_2, tvb, offset, 2, FALSE);
#if 0
						if (tlv_len == 1)
						{
							proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_reserved1, tvb, offset, 2, FALSE);
						}
						else
#endif
						{
							proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_cc_ir_2, tvb, offset , 2, FALSE);
							proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_ldpc_2, tvb, offset, 2, FALSE);
							proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_dedicated_pilots_2, tvb, offset, 2, FALSE);
							proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_reserved1_2, tvb, offset, 2, FALSE);
						}
					}
				break;
				case SBC_SS_MODULATOR:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_modulator, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_64qam, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_btc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_ctc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_stc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_harq_chase, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_ctc_ir, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_cc_ir, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_ldpc, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_NUM_UL_ARQ_ACK_CHANNEL:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_number_ul_arq_ack_channel, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_number_ul_arq_ack_channel, tvb, offset, tlv_len, FALSE);
				break;
				case SBC_SS_NUM_DL_ARQ_ACK_CHANNEL:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_number_dl_arq_ack_channel, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					/* get and save the value */
					num_dl_harq_chans = tvb_get_guint8(tvb, offset);
					proto_tree_add_item(tlv_tree, hf_sbc_number_dl_arq_ack_channel, tvb, offset, tlv_len, FALSE);
				break;
				case SBC_SS_PERMUTATION_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_permutation_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_optimal_pusc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_optimal_fusc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_1x6, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_2x3, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_3x2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_with_harq_map, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_tusc1_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_tusc2_support, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_DEMODULATOR_MIMO_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_demodulator_mimo_support, tvb, offset, 2, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_a, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_vertical, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_horizontal, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_a, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_vertical, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_horizontal, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_vertical, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_horizontal, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_rsvd, tvb, offset, 2, FALSE);
				break;
				case SBC_SS_MIMO_UPLINK_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_mimo_uplink_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_2_ann_sttd, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_2_ann_sm_vertical, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_1_ann_coop_sm, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_rsvd, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_OFDMA_AAS_PRIVATE_MAP_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_ofdma_aas_private, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_harq_map_capability, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_map_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_reduced_private_map_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_chain_enable, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_map_dl_frame_offset, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_ul_frame_offset, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_map_concurrency, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_OFDMA_AAS_CAPABILITIES:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ofdma_aas_capabilities, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_zone, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_diversity_map_scan, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_fbck_rsp_support, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_downlink_aas_preamble, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_uplink_aas_preamble, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_capabilities_rsvd, tvb, offset, 2, FALSE);
				break;
				case SBC_SS_CINR_MEASUREMENT_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_cinr_measure_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_phy_cinr_measurement_preamble, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_pilot_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_data_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_effective_cinr_measurement_preamble, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_pilot_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_data_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_support_2_concurrent_cqi_channels,tvb,offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_frequency_selectivity_characterization_report,tvb,offset, 1, FALSE);
				break;
				case SBC_PKM_FLOW_CONTROL:
					if (!include_cor2_changes)
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_pkm_flow_control, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						tlv_item = proto_tree_add_item(tlv_tree, hf_sbc_pkm_flow_control, tvb, offset, tlv_len, FALSE);
						if(tvb_get_guint8(tvb, offset) == 0)
							proto_item_append_text(tlv_item, " (default - no limit)");
					}
					else
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_power_save_class_types_capability, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						proto_tree_add_item(tlv_tree, hf_sbc_unknown_type, tvb, offset, tlv_len, FALSE);
					}
				break;
				case SBC_AUTH_POLICY_SUPPORT:
					/* display the TLV name and display the value in hex */
					tlv_item = proto_tree_add_item(sbc_tree, hf_sbc_auth_policy, tvb, offset, tlv_len, FALSE);
					/* add TLV subtree */
					tlv_tree = proto_item_add_subtree(tlv_item, ett_sbc_req_tlv_subtree);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_privacy_802_16, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_privacy_rsvd, tvb, offset, 1, FALSE);
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_auth_policy, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_privacy_802_16, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_privacy_rsvd, tvb, offset, 1, FALSE);
					if (!include_cor2_changes)
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_auth_policy, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						proto_tree_add_item(tlv_tree, hf_sbc_privacy_802_16, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_privacy_rsvd, tvb, offset, 1, FALSE);
					}
					else
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_power_save_class_types_capability, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						proto_tree_add_item(tlv_tree, hf_sbc_unknown_type, tvb, offset, tlv_len, FALSE);
					}
				break;
				case SBC_MAX_SECURITY_ASSOCIATIONS:
					if (!include_cor2_changes)
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_max_security_associations, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						proto_tree_add_item(tlv_tree, hf_sbc_max_security_associations, tvb, offset, tlv_len, FALSE);
					}
					else
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_power_save_class_types_capability, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						proto_tree_add_item(tlv_tree, hf_sbc_unknown_type, tvb, offset, tlv_len, FALSE);
					}
				break;
				case SBC_TLV_T_27_EXTENSION_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_27_extension_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_27_extension_capability_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_27_extension_capability_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_28_HO_TRIGGER_METRIC_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit1, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit3, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_167_ASSOCIATION_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_167_association_type_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit1, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit3, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit4, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_170_UPLINK_POWER_CONTROL_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ofdma_ss_uplink_power_control_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_ss_uplink_power_control_support_open_loop, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_ss_uplink_power_control_support_aas_preamble, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_ss_uplink_power_control_support_rsvd, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_171_MINIMUM_NUM_OF_FRAMES:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_171_minimum_num_of_frames, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_171_minimum_num_of_frames, tvb, offset, tlv_len, FALSE);
				break;
				case SBC_TLV_T_172:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_172, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_harq_map_capability, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_extended_harq_ie_capability, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_sub_map_capability_first_zone, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_sub_map_capability_other_zones, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_dl_region_definition_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_173_UL_CONTROL_CHANNEL_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_173_ul_ctl_channel_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_3_bit_mimo_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_enhanced_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_ul_ack, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_reserved, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_uep_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_measurement_report, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_primary_secondary_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_diuc_cqi_fast_feedback, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_174_OFDMA_MS_CSIT_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_174_ofdma_ms_csit_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_csit_compatibility_type_a, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_csit_compatibility_type_b, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_power_assignment_capability, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_sounding_rsp_time_capability, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_max_num_simultanous_sounding_instructions, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_ss_csit_type_a_support, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_ss_csit_reserved, tvb, offset, 2, FALSE);
				break;
				case SBC_TLV_T_175_MAX_NUM_BST_PER_FRM_CAPABILITY_HARQ:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_175_max_num_bst_per_frm_capability_harq, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_175_max_num_ul_harq_bst, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_175_max_num_ul_harq_per_frm_include_one_non_harq_bst, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_175_max_num_dl_harq_bst_per_harq_per_frm, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_176: /* TODO: Get an invalid TLV whenever this TLV is used. Could it be
						       that lengths above 2 cause this problem? */
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_176, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit0, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit1, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit2, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit3, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit4, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit5, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit6, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit7, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit8, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit9, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit10, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit11, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit12, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit13, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit14, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit15, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit16, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit17, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit18, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit19, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_reserved, tvb, offset, 3, FALSE);
				break;
				case SBC_TLV_T_177_OFDMA_SS_MODULATOR_FOR_MIMO_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_177_ofdma_ss_modulator_for_mimo_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					if (include_cor2_changes)
					{
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_stc_matrix_a, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_stc_matrix_b_vertical, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_stc_matrix_b_horizontal, tvb, offset, 1, FALSE);
					} else {
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_two_transmit_antennas, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_capable_of_transmit_diversity, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_capable_of_spacial_multiplexing, tvb, offset, 1, FALSE);
					}
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_beamforming, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_adaptive_rate_ctl, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_single_antenna, tvb, offset, 1, FALSE);
					if (include_cor2_changes)
					{
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_collaborative_sm_with_one_antenna, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_collaborative_sm_with_two_antennas, tvb, offset, 1, FALSE);
					} else {
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_capable_of_two_antenna, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_rsvd, tvb, offset, 1, FALSE);
					}
				break;
				case SBC_TLV_T_178_SDMA_PILOT_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_178_sdma_pilot_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_178_sdma_pilot_pattern_support_for_amc_zone, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_178_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_179_OFDMA_MULTIPLE_DL_BURST_PROFILE_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_179_ofdma_multiple_dl_burst_profile_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_179_dl_bst_profile_for_multiple_fec, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_179_ul_bst_profile_for_multiple_fec, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_179_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_204_OFDMA_PARAMETERS_SETS:
					if (include_cor2_changes)
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_a, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_b, tvb, offset, 1, FALSE);
						tlv_item = proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_harq_parameters_set, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_a, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_b, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_reserved, tvb, offset, 1, FALSE);
					}
					break;
				case SBC_TLV_T_162_HARQ_INCREMENTAL_REDUNDANCY_BUFFER_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_NEP, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_dl, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved1, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_ul_harq_incremental_redundancy_buffer_capability_NEP, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_ul, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved2, tvb, offset, 2, FALSE);
				break;
				case SBC_TLV_T_163_HARQ_CHASE_COMBINING_AND_CC_IR_BUFFER_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_dl_harq_buffering_capability_for_chase_combining, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_dl, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved1, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_ul_harq_buffering_capability_for_chase_combining, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_ul, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved2, tvb, offset, 2, FALSE);
				break;
				case PKM_ATTR_SECURITY_NEGOTIATION_PARAMETERS:
					/* display Security Negotiation Parameters Title */
					/* add Security Negotiation Parameters subtree */
					tlv_tree = add_protocol_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, proto_mac_mgmt_msg_sbc_decoder, tvb, offset, tlv_len, "Security Negotiation Parameters (%u bytes)", tlv_len);
					/* call the Security Negotiation Parameters decoder */
					wimax_security_negotiation_parameters_decoder(tvb_new_subset(tvb, offset, tlv_len, tlv_len), pinfo, tlv_tree);
				break;
				case SBC_TLV_T_26_POWER_SAVE_CLASS_TYPES_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_power_save_class_types_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bit1, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bit2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bits34, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bits567, tvb, offset, 1, FALSE);
				break;
				default:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_power_save_class_types_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_unknown_type, tvb, offset, tlv_len, FALSE);
				break;
			}
			offset += tlv_len;
		}	/* end of TLV process while loop */
	}
}

/* Wimax Mac SBC-RSP Message Dissector */
void dissect_mac_mgmt_msg_sbc_rsp_decoder(tvbuff_t *tvb, packet_info *pinfo, proto_tree *tree)
{
	guint offset = 0;
	guint tvb_len, payload_type, value;
	gint  tlv_type, tlv_len, tlv_value_offset;
/*	guint ssttg, ssrtg;*/
	guint num_dl_harq_chans; /*, num_ul_harq_chans;*/
	proto_item *sbc_item = NULL;
	proto_tree *sbc_tree = NULL;
	proto_item *tlv_item = NULL;
	proto_tree *tlv_tree = NULL;
	proto_item *ti = NULL;
	tlv_info_t tlv_info;
	gfloat power_bpsk;
	gfloat power_qpsk;
	gfloat power_qam16;
	gfloat power_qam64;
	gfloat current_power;

	/* Ensure the right payload type */
	payload_type = tvb_get_guint8(tvb, offset);
	if (payload_type != MAC_MGMT_MSG_SBC_RSP)
	{
		return;
	}

	if (tree)
	{	/* we are being asked for details */
		/* Get the tvb reported length */
		tvb_len =  tvb_reported_length(tvb);
		/* display MAC payload type SBC-RSP */
		sbc_item = proto_tree_add_protocol_format(tree, proto_mac_mgmt_msg_sbc_decoder, tvb, offset, tvb_len, "SS Basic Capability Response (SBC-RSP) (%u bytes)", tvb_len);
		/* add MAC SBC subtree */
		sbc_tree = proto_item_add_subtree(sbc_item, ett_mac_mgmt_msg_sbc_decoder);
		/* Decode and display the SS Basic Capability Response (SBC-RSP) */
		/* display the Message Type */
		proto_tree_add_item(sbc_tree, hf_sbc_rsp_message_type, tvb, offset, 1, FALSE);
		/* set the offset for the TLV Encoded info */
		offset++;
		/* process the SBC TLVs */
		while(offset < tvb_len)
		{
			/* get the TLV information */
			init_tlv_info(&tlv_info, tvb, offset);
			/* get the TLV type */
			tlv_type = get_tlv_type(&tlv_info);
			/* get the TLV length */
			tlv_len = get_tlv_length(&tlv_info);
			if (tlv_type == -1 || tlv_len > MAX_TLV_LEN || tlv_len < 1)
			{	/* invalid tlv info */
				col_append_sep_str(pinfo->cinfo, COL_INFO, NULL, "SBC-RSP TLV error");
				proto_tree_add_item(sbc_tree, hf_sbc_invalid_tlv, tvb, offset, (tvb_len - offset), FALSE);
				break;
			}
			if (tlv_type == 0)
			{	/* invalid tlv type */
				col_append_sep_str(pinfo->cinfo, COL_INFO, NULL, "Invalid SBC TLV type");
				proto_tree_add_item(sbc_tree, hf_sbc_unknown_type, tvb, offset, 1, FALSE);
				offset++;
				continue;
			}
			/* get the TLV value offset */
			tlv_value_offset = get_tlv_value_offset(&tlv_info);
#ifdef DEBUG /* for debug only */
			proto_tree_add_protocol_format(sbc_tree, proto_mac_mgmt_msg_sbc_decoder, tvb, offset, (tlv_len + tlv_value_offset), "SBC-RSP Type: %u (%u bytes, offset=%u, tlv_len=%u, tvb_len=%u)", tlv_type, (tlv_len + tlv_value_offset), offset, tlv_len, tvb_len);
#endif
			/* update the offset for the TLV value */
			offset += tlv_value_offset;
			/* process SBC TLV Encoded information */
			switch (tlv_type)
			{
				case SBC_BW_ALLOC_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_bw_alloc_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_bw_alloc_support_rsvd0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_bw_alloc_support_duplex, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_bw_alloc_support_rsvd1, tvb, offset, 1, FALSE);
				break;
				case SBC_TRANSITION_GAPS:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_transition_gaps, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					ti = proto_tree_add_item(tlv_tree, hf_sbc_ssttg, tvb, offset, 1, FALSE);
					proto_item_append_text(ti, " us (ranges: TDD 0-50; H-FDD 0-100)");
					ti = proto_tree_add_item(tlv_tree, hf_sbc_ssrtg, tvb, (offset + 1), 1, FALSE);
					proto_item_append_text(ti, " us (ranges: TDD 0-50; H-FDD 0-100)");
				break;
				case SBC_MAC_PDU:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_mac_pdu, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_mac_pdu_piggybacked, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_mac_pdu_fsn, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_mac_pdu_rsvd, tvb, offset, 1, FALSE);
				break;
				case SBC_REQ_MAX_TRANSMIT_POWER:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_max_transmit_power, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					power_bpsk = (gfloat)(tvb_get_guint8(tvb, offset) - 128) / 2;
					power_qpsk = (gfloat)(tvb_get_guint8(tvb, (offset + 1)) - 128) / 2;
					power_qam16 = (gfloat)(tvb_get_guint8(tvb, (offset + 2)) - 128) / 2;
					power_qam64 = (gfloat)(tvb_get_guint8(tvb, (offset + 3)) - 128) / 2;
					proto_tree_add_text(tlv_tree, tvb, offset, 1, "BPSK: %.2f dBm", (gdouble)power_bpsk);
					proto_tree_add_text(tlv_tree, tvb, (offset + 1), 1, "QPSK: %.2f dBm", (gdouble)power_qpsk);
					proto_tree_add_text(tlv_tree, tvb, (offset + 2), 1, "QAM16: %.2f dBm", (gdouble)power_qam16);
					proto_tree_add_text(tlv_tree, tvb, (offset + 3), 1, "QAM64: %.2f dBm", (gdouble)power_qam64);
				break;
				case SBC_REQ_CURR_TRANSMITTED_POWER:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_curr_transmit_power, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					value = tvb_get_guint8(tvb, offset);
					current_power = (gfloat)(value - 128) / 2;
					proto_tree_add_text(tlv_tree, tvb, offset, 1, "Current Transmitted Power: %.2f dBm (Value: 0x%x)", (gdouble)current_power, value);
				break;
				case SBC_SS_FFT_SIZES:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ss_fft_sizes, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					if (include_cor2_changes)
					{
						proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_rsvd1, tvb, offset, 1, FALSE);
					} else {
						proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_256, tvb, offset, 1, FALSE);
					}
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_2048, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_128, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_512, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_1024, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_fft_rsvd2, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_DEMODULATOR:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ss_demodulator, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					if (tlv_len == 1) /* && (num_dl_harq_chans < 8)) */
					{
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_64qam, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_btc, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_ctc, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_stc, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_cc_with_optional_interleaver, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_chase, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_ctc_ir, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_reserved, tvb, offset, 1, FALSE);
					}
					else
					{
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_64qam_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_btc_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_ctc_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_stc_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_cc_with_optional_interleaver_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_chase_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_ctc_ir_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_reserved_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_harq_cc_ir_2, tvb, offset , 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_ldpc_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_dedicated_pilots_2, tvb, offset, 2, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_reserved1_2, tvb, offset, 2, FALSE);
					}
				break;
				case SBC_SS_MODULATOR:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_req_tlv_subtree, sbc_tree, hf_sbc_ss_modulator, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_64qam, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_btc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_ctc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_stc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_harq_chase, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_ctc_ir, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_cc_ir, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_modulator_ldpc, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_NUM_UL_ARQ_ACK_CHANNEL:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_number_ul_arq_ack_channel, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_number_ul_arq_ack_channel, tvb, offset, tlv_len, FALSE);
				break;
				case SBC_SS_NUM_DL_ARQ_ACK_CHANNEL:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_number_dl_arq_ack_channel, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					/* get and save the value */
					num_dl_harq_chans = tvb_get_guint8(tvb, offset);
					proto_tree_add_item(tlv_tree, hf_sbc_number_dl_arq_ack_channel, tvb, offset, tlv_len, FALSE);
				break;
				case SBC_SS_PERMUTATION_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ss_permutation_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_optimal_pusc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_optimal_fusc, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_1x6, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_2x3, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_3x2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_amc_with_harq_map, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_tusc1_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_tusc2_support, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_DEMODULATOR_MIMO_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ss_demodulator_mimo_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_a, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_vertical, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_horizontal, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_a, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_vertical, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_horizontal, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_vertical, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_horizontal, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_demodulator_mimo_rsvd, tvb, offset, 2, FALSE);
				break;
				case SBC_SS_MIMO_UPLINK_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ss_mimo_uplink_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_2_ann_sttd, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_2_ann_sm_vertical, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_1_ann_coop_sm, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_mimo_uplink_support_rsvd, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_OFDMA_AAS_PRIVATE_MAP_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ss_ofdma_aas_private, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_harq_map_capability, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_map_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_reduced_private_map_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_chain_enable, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_map_dl_frame_offset, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_ul_frame_offset, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_aas_private_map_concurrency, tvb, offset, 1, FALSE);
				break;
				case SBC_SS_OFDMA_AAS_CAPABILITIES:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ofdma_aas_capabilities, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_zone, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_diversity_map_scan, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_fbck_rsp_support, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_downlink_aas_preamble, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_uplink_aas_preamble, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_ofdma_aas_capabilities_rsvd, tvb, offset, 2, FALSE);
				break;
				case SBC_SS_CINR_MEASUREMENT_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ss_cinr_measure_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ss_phy_cinr_measurement_preamble, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_pilot_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_data_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_effective_cinr_measurement_preamble, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_pilot_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_data_subcarriers, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_support_2_concurrent_cqi_channels,tvb,offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ss_frequency_selectivity_characterization_report,tvb,offset, 1, FALSE);
				break;
				case SBC_PKM_FLOW_CONTROL:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_pkm_flow_control, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					tlv_item = proto_tree_add_item(tlv_tree, hf_sbc_pkm_flow_control, tvb, offset, tlv_len, FALSE);
					if (tvb_get_guint8(tvb, offset) == 0)
					{
						proto_item_append_text(tlv_item, " (default - no limit)");
					}
				break;
				case SBC_AUTH_POLICY_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_auth_policy, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_privacy_802_16, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_privacy_rsvd, tvb, offset, 1, FALSE);
				break;
				case SBC_MAX_SECURITY_ASSOCIATIONS:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_max_security_associations, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_max_security_associations, tvb, offset, tlv_len, FALSE);
				break;
				case SBC_TLV_T_27_EXTENSION_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_27_extension_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_27_extension_capability_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_27_extension_capability_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_28_HO_TRIGGER_METRIC_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit1, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_bit3, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_28_ho_trigger_metric_support_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_167_ASSOCIATION_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_167_association_type_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit1, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit3, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_bit4, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_167_association_type_support_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_170_UPLINK_POWER_CONTROL_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_ofdma_ss_uplink_power_control_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_ss_uplink_power_control_support_open_loop, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_ss_uplink_power_control_support_aas_preamble, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_ofdma_ss_uplink_power_control_support_rsvd, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_171_MINIMUM_NUM_OF_FRAMES:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_171_minimum_num_of_frames, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_171_minimum_num_of_frames, tvb, offset, tlv_len, FALSE);
				break;
				case SBC_TLV_T_172:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_172, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_harq_map_capability, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_extended_harq_ie_capability, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_sub_map_capability_first_zone, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_sub_map_capability_other_zones, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_dl_region_definition_support, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_172_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_173_UL_CONTROL_CHANNEL_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_173_ul_ctl_channel_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_3_bit_mimo_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_enhanced_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_ul_ack, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_reserved, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_uep_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_measurement_report, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_primary_secondary_fast_feedback, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_173_diuc_cqi_fast_feedback, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_174_OFDMA_MS_CSIT_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_174_ofdma_ms_csit_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_csit_compatibility_type_a, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_csit_compatibility_type_b, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_power_assignment_capability, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_sounding_rsp_time_capability, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_max_num_simultanous_sounding_instructions, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_ss_csit_type_a_support, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_174_ss_csit_reserved, tvb, offset, 2, FALSE);
				break;
				case SBC_TLV_T_175_MAX_NUM_BST_PER_FRM_CAPABILITY_HARQ:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_175_max_num_bst_per_frm_capability_harq, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_175_max_num_ul_harq_bst, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_175_max_num_ul_harq_per_frm_include_one_non_harq_bst, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_175_max_num_dl_harq_bst_per_harq_per_frm, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_176:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_176, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit0, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit1, tvb, offset, 3, FALSE);
					if (include_cor2_changes)
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit2_cor2, tvb, offset, 3, FALSE);
					else
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit2, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit3, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit4, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit5, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit6, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit7, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit8, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit9, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit10, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit11, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit12, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit13, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit14, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit15, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit16, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit17, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit18, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_bit19, tvb, offset, 3, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_176_reserved, tvb, offset, 3, FALSE);
				break;
				case SBC_TLV_T_177_OFDMA_SS_MODULATOR_FOR_MIMO_SUPPORT:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_177_ofdma_ss_modulator_for_mimo_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					if (include_cor2_changes)
					{
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_stc_matrix_a, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_stc_matrix_b_vertical, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_stc_matrix_b_horizontal, tvb, offset, 1, FALSE);
					} else {
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_two_transmit_antennas, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_capable_of_transmit_diversity, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_capable_of_spacial_multiplexing, tvb, offset, 1, FALSE);
					}
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_beamforming, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_adaptive_rate_ctl, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_single_antenna, tvb, offset, 1, FALSE);
					if (include_cor2_changes)
					{
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_collaborative_sm_with_one_antenna, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_collaborative_sm_with_two_antennas, tvb, offset, 1, FALSE);
					} else {
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_capable_of_two_antenna, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_177_rsvd, tvb, offset, 1, FALSE);
					}
				break;
				case SBC_TLV_T_178_SDMA_PILOT_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_178_sdma_pilot_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_178_sdma_pilot_pattern_support_for_amc_zone, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_178_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_179_OFDMA_MULTIPLE_DL_BURST_PROFILE_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_179_ofdma_multiple_dl_burst_profile_support, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_179_dl_bst_profile_for_multiple_fec, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_179_ul_bst_profile_for_multiple_fec, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_179_reserved, tvb, offset, 1, FALSE);
				break;
				case SBC_TLV_T_204_OFDMA_PARAMETERS_SETS:
					if (include_cor2_changes)
					{
						/* add TLV subtree */
						tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets, tvb, offset, tlv_len, FALSE);
						/* display the detail meanings of the TLV value */
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_a, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_b, tvb, offset, 1, FALSE);
						tlv_item = proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_harq_parameters_set, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_a, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_b, tvb, offset, 1, FALSE);
						proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_204_ofdma_parameters_sets_reserved, tvb, offset, 1, FALSE);
					}
					break;
				case SBC_TLV_T_162_HARQ_INCREMENTAL_REDUNDANCY_BUFFER_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_NEP, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_dl, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved1, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_ul_harq_incremental_redundancy_buffer_capability_NEP, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_ul, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved2, tvb, offset, 2, FALSE);
				break;
				case SBC_TLV_T_163_HARQ_CHASE_COMBINING_AND_CC_IR_BUFFER_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_dl_harq_buffering_capability_for_chase_combining, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_dl, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved1, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_ul_harq_buffering_capability_for_chase_combining, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_ul, tvb, offset, 2, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved2, tvb, offset, 2, FALSE);
				break;
				case PKM_ATTR_SECURITY_NEGOTIATION_PARAMETERS:
					/* display Security Negotiation Parameters Title */
					tlv_item = proto_tree_add_protocol_format(sbc_tree, proto_mac_mgmt_msg_sbc_decoder, tvb, offset, tvb_len, "Security Negotiation Parameters (%u bytes)", tvb_len);
					/* add Security Negotiation Parameters subtree */
					tlv_tree = proto_item_add_subtree(tlv_item, ett_sbc_rsp_tlv_subtree);
					/* call the Security Negotiation Parameters decoder */
					wimax_security_negotiation_parameters_decoder(tvb_new_subset(tvb, offset, tlv_len, tlv_len), pinfo, tlv_tree);
				break;
				case SBC_TLV_T_26_POWER_SAVE_CLASS_TYPES_CAPABILITY:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_power_save_class_types_capability, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bit0, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bit1, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bit2, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bits34, tvb, offset, 1, FALSE);
					proto_tree_add_item(tlv_tree, hf_sbc_power_save_class_types_capability_bits567, tvb, offset, 1, FALSE);
				break;
				default:
					/* add TLV subtree */
					tlv_tree = add_tlv_subtree(&tlv_info, ett_sbc_rsp_tlv_subtree, sbc_tree, hf_sbc_unknown_type, tvb, offset, tlv_len, FALSE);
					/* display the detail meanings of the TLV value */
					proto_tree_add_item(tlv_tree, hf_sbc_unknown_type, tvb, offset, tlv_len, FALSE);
				break;
			}
			offset += tlv_len;
		}	/* end of TLV process while loop */
	}
}

/* Register Wimax Mac SBC-REQ/RSP Messages Dissectors */
void proto_register_mac_mgmt_msg_sbc(void)
{
	/* SBC display */
	static hf_register_info hf_sbc[] =
	{
		{	/* 11.8.8 */
			&hf_sbc_tlv_t_167_association_type_support,
			{
				"Association Type Support", "wmx.sbc.association_type_support",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_167_association_type_support_bit0,
			{
				"Scanning Without Association: association not supported", "wmx.sbc.association_type_support.bit0",
				FT_BOOLEAN, 8,	TFS(&tfs_yes_no_sbc), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_167_association_type_support_bit1,
			{
				"Association Level 0: scanning or association without coordination", "wmx.sbc.association_type_support.bit1",
				FT_BOOLEAN, 8, TFS(&tfs_yes_no_sbc), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_167_association_type_support_bit2,
			{
				"Association Level 1: association with coordination", "wmx.sbc.association_type_support.bit2",
				FT_BOOLEAN, 8, TFS(&tfs_yes_no_sbc), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_167_association_type_support_bit3,
			{
				"Association Level 2: network assisted association", "wmx.sbc.association_type_support.bit3",
				FT_BOOLEAN, 8, TFS(&tfs_yes_no_sbc), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_167_association_type_support_bit4,
			{
				"Desired Association Support", "wmx.sbc.association_type_support.bit4",
				FT_BOOLEAN, 8, TFS(&tfs_yes_no_sbc), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_167_association_type_support_reserved,
			{
				"Reserved", "wmx.sbc.association_type_support.reserved",
				FT_UINT8, BASE_HEX, NULL, 0xE0, NULL, HFILL
			}
		},
		{	/* 11.7.8.7 */
			&hf_sbc_auth_policy,
			{
				"Authorization Policy Support", "wmx.sbc.auth_policy",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_privacy_802_16,
			{
				"IEEE 802.16 Privacy", "wmx.sbc.auth_policy.802_16",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_privacy_rsvd,
			{
				"Reserved", "wmx.sbc.auth_policy.rsvd",
				FT_UINT8, BASE_HEX, NULL, 0xFE, NULL, HFILL
			}
		},
		{	/* 11.8.1 */
			&hf_sbc_bw_alloc_support,
			{
				"Bandwidth Allocation Support", "wmx.sbc.bw_alloc_support",
				FT_UINT8, BASE_HEX, NULL, 0x00, NULL, HFILL
			}
		},
		{
			&hf_sbc_bw_alloc_support_duplex,
			{
				"Duplex", "wmx.sbc.bw_alloc_support.duplex",
				FT_BOOLEAN, 8, TFS(&tfs_sbc_bw_alloc_support_duplex), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_bw_alloc_support_rsvd0,
			{
				"Reserved", "wmx.sbc.bw_alloc_support.rsvd0",
				FT_UINT8, BASE_HEX, NULL, 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_bw_alloc_support_rsvd1,
			{
				"Reserved", "wmx.sbc.bw_alloc_support.rsvd1",
				FT_UINT8, BASE_HEX, NULL, 0xFC, NULL, HFILL
			}
		},
		{
			&hf_sbc_curr_transmit_power,
			{
				"Current transmitted power", "wmx.sbc.curr_transmit_power",
				FT_UINT8, BASE_HEX, NULL, 0x00, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_effective_cinr_measurement_preamble,
			{
				"Effective CINR Measurement For A Permutation Zone From Preamble", "wmx.sbc.effective_cinr_measure_permutation_zone_preamble",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_pilot_subcarriers,
			{
				"Effective CINR Measurement For A Permutation Zone From Pilot Subcarriers", "wmx.sbc.effective_cinr_measure_permutation_zone.pilot_subcarriers",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_effective_cinr_measurement_permutation_zone_from_data_subcarriers,
			{
				"Effective CINR Measurement For A Permutation Zone From Data Subcarriers", "wmx.sbc.effective_cinr_measure_permutation_zone.data_subcarriers",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{	/* 11.8.6 */
			&hf_sbc_tlv_t_27_extension_capability,
			{
				"Extension Capability", "wmx.sbc.extension_capability",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_27_extension_capability_bit0,
			{
				"Supported Extended Subheader Format", "wmx.sbc.extension_capability.bit0",
				FT_BOOLEAN, 8, TFS(&tfs_yes_no_sbc), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_27_extension_capability_reserved,
			{
				"Reserved", "wmx.sbc.extension_capability.reserved",
				FT_UINT8, BASE_HEX, NULL, 0xFE, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_frequency_selectivity_characterization_report,
			{
				"Frequency Selectivity Characterization Report", "wmx.sbc.frequency_selectivity_characterization_report",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x80, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.19.2 */
			&hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability,
			{
				"HARQ Chase Combining And CC-IR Buffer Capability", "wmx.sbc.harq_chase_combining_and_cc_ir_buffer_capability",
				FT_UINT16, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_dl,
			{
				"Aggregation Flag For DL", "wmx.sbc.harq_chase_combining_and_cc_ir_buffer_capability.aggregation_flag_dl",
				FT_UINT16, BASE_HEX, NULL, 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_aggregation_flag_ul,
			{
				"Aggregation Flag for UL", "wmx.sbc.harq_chase_combining_and_cc_ir_buffer_capability.aggregation_flag_ul",
				FT_UINT16, BASE_HEX, NULL, 0x4000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_163_dl_harq_buffering_capability_for_chase_combining,
			{
				"Downlink HARQ Buffering Capability For Chase Combining (K)", "wmx.sbc.harq_chase_combining_and_cc_ir_buffer_capability.dl_harq_buffering_capability_for_chase_combining",
				FT_UINT16, BASE_HEX, NULL, 0x3F, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved1,
			{
				"Reserved", "wmx.sbc.harq_chase_combining_and_cc_ir_buffer_capability.reserved1",
				FT_UINT16, BASE_HEX, NULL, 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_163_harq_chase_combining_and_cc_ir_buffer_capability_reserved2,
			{
				"Reserved", "wmx.sbc.harq_chase_combining_and_cc_ir_buffer_capability.reserved2",
				FT_UINT16, BASE_HEX, NULL, 0x8000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_163_ul_harq_buffering_capability_for_chase_combining,
			{
				"Uplink HARQ buffering capability for chase combining (K)", "wmx.sbc.harq_chase_combining_and_cc_ir_buffer_capability.ul_harq_buffering_capability_for_chase_combining",
				FT_UINT16, BASE_HEX, NULL, 0x3F00, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.19.1 */
			&hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability,
			{
				"HARQ Incremental Buffer Capability", "wmx.sbc.harq_incremental_redundancy_buffer_capability",
				FT_UINT16, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_dl,
			{
				"Aggregation Flag for DL", "wmx.sbc.harq_incremental_redundancy_buffer_capability.aggregation_flag_for_dl",
				FT_UINT16, BASE_HEX, NULL, 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_aggregation_flag_for_ul,
			{
				"Aggregation Flag For UL", "wmx.sbc.harq_incremental_redundancy_buffer_capability.aggregation_flag_for_ul",
				FT_UINT16, BASE_HEX, NULL, 0x1000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_NEP,
			{
				"NEP Value Indicating Downlink HARQ Buffering Capability For Incremental Redundancy CTC", "wmx.sbc.harq_incremental_redundancy_buffer_capability.dl_incremental_redundancy_ctc",
				FT_UINT16, BASE_HEX, NULL, 0xF, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved1,
			{
				"Reserved", "wmx.sbc.harq_incremental_redundancy_buffer_capability.reserved",
				FT_UINT16, BASE_HEX, NULL, 0xE0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_162_harq_incremental_redundancy_buffer_capability_reserved2,
			{
				"Reserved", "wmx.sbc.harq_incremental_redundancy_buffer_capability.reserved2",
				FT_UINT16, BASE_HEX, NULL, 0xE000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_162_ul_harq_incremental_redundancy_buffer_capability_NEP,
			{
				"NEP Value Indicating Uplink HARQ Buffering Capability For Incremental Redundancy CTC", "wmx.sbc.harq_incremental_redundancy_buffer_capability.ul_incremental_redundancy_ctc",
				FT_UINT16,BASE_HEX, NULL, 0xF00, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_aas_harq_map_capability,
			{
				"H-ARQ MAP Capability", "wmx.sbc.harq_map_capability",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{	/* 11.8.7 */
			&hf_sbc_tlv_t_28_ho_trigger_metric_support,
			{
				"HO Trigger Metric Support", "wmx.sbc.ho_trigger_metric_support",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_28_ho_trigger_metric_support_bit0,
			{
				"BS CINR Mean", "wmx.sbc.ho_trigger_metric_support.bit0",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_28_ho_trigger_metric_support_bit1,
			{
				"BS RSSI Mean", "wmx.sbc.ho_trigger_metric_support.bit1",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_28_ho_trigger_metric_support_bit2,
			{
				"BS Relative Delay", "wmx.sbc.ho_trigger_metric_support.bit2",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_28_ho_trigger_metric_support_bit3,
			{
				"BS RTD", "wmx.sbc.ho_trigger_metric_support.bit3",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_28_ho_trigger_metric_support_reserved,
			{
				"Reserved", "wmx.sbc.ho_trigger_metric_support.reserved",
				FT_UINT8, BASE_HEX, NULL, 0xF0, NULL, HFILL
			}
		},
		{
			&hf_sbc_invalid_tlv,
			{
				"Invalid TLV", "wmx.sbc.invalid_tlv",
				FT_BYTES, BASE_NONE, NULL, 0x0, NULL, HFILL
			}
		},
		{	/* 11.8.2 */
			&hf_sbc_mac_pdu,
			{
				"Capabilities For Construction And Transmission Of MAC PDUs", "wmx.sbc.mac_pdu",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_mac_pdu_piggybacked,
			{
				"Ability To Receive Requests Piggybacked With Data", "wmx.sbc.mac_pdu.bit0",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_mac_pdu_fsn,
			{
				"Ability To Use 3-bit FSN Values Used When Forming MAC PDUs On Non-ARQ Connections", "wmx.sbc.mac_pdu.bit1",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.15 */
			&hf_sbc_tlv_t_175_max_num_bst_per_frm_capability_harq,
			{
				"Maximum Number Of Burst Per Frame Capability In HARQ", "wmx.sbc.max_num_bst_per_frm_capability_harq",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_175_max_num_dl_harq_bst_per_harq_per_frm,
			{
				"Maximum Numbers Of DL HARQ Bursts Per HARQ Enabled Of MS Per Frame (default(0)=1)", "wmx.sbc.max_num_bst_per_frm_capability_harq.max_num_dl_harq_bst_per_harq_per_frm",
				FT_UINT8, BASE_DEC, NULL, 0xF0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_175_max_num_ul_harq_bst,
			{
				"Maximum Number Of UL HARQ Burst Per HARQ Enabled MS Per Frame (default(0)=1)", "wmx.sbc.max_num_bst_per_frm_capability_harq.max_num_ul_harq_bst",
				FT_UINT8, BASE_DEC, NULL, 0x7, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_175_max_num_ul_harq_per_frm_include_one_non_harq_bst,
			{
				"Whether The Maximum Number Of UL HARQ Bursts Per Frame (i.e. Bits# 2-0) Includes The One Non-HARQ Burst", "wmx.sbc.max_num_bst_per_frm_capability_harq.max_num_ul_harq_per_frm_include_one_non_harq_bst",
				FT_BOOLEAN, 8, TFS(&tfs_yes_no_sbc), 0x8, NULL, HFILL
			}
		},
		{	/* 11.7.8.8 */
			&hf_sbc_max_security_associations,
			{
				"Maximum Number Of Security Association Supported By The SS", "wmx.sbc.max_security_associations",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.2 - type 161 */
			&hf_sbc_number_dl_arq_ack_channel,
			{
				"The Number Of DL HARQ ACK Channel", "wmx.sbc.number_dl_arq_ack_channel",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.3 - type 153 */
			&hf_sbc_number_ul_arq_ack_channel,
			{
				"The Number Of UL HARQ ACK Channel", "wmx.sbc.number_ul_arq_ack_channel",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.8 */
			&hf_sbc_ofdma_aas_capabilities,
			{
				"OFDMA AAS Capability", "wmx.sbc.ofdma_aas_capability",
				FT_UINT16, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_ofdma_aas_capabilities_rsvd,
			{
				"Reserved", "wmx.sbc.ofdma_aas_capabilities.rsvd",
				FT_UINT16, BASE_HEX, NULL, 0xFFE0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_ofdma_aas_diversity_map_scan,
			{
				"AAS Diversity Map Scan (AAS DLFP)", "wmx.sbc.ofdma_aas_diversity_map_scan",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_ofdma_aas_fbck_rsp_support,
			{
				"AAS-FBCK-RSP Support", "wmx.sbc.ofdma_aas_fbck_rsp_support",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_ofdma_aas_zone,
			{
				"AAS Zone", "wmx.sbc.ofdma_aas_zone",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_ofdma_downlink_aas_preamble,
			{
				"Downlink AAS Preamble", "wmx.sbc.ofdma_downlink_aas_preamble",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.5 - 3 bytes */
			&hf_sbc_tlv_t_176,
			{
				"OFDMA MS Demodulator For MIMO Support In DL", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl",
				FT_BOOLEAN, BASE_NONE, TFS(&tfs_supported), 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit0,
			{
				"2-antenna STC Matrix A", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit0",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit1,
			{
				"2-antenna STC Matrix B, vertical coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit1",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit2,
			{
				"Four Receive Antennas", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit2",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit2_cor2,
			{
				"2-antenna STC matrix B, horizontal coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit2",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit3,
			{
				"4-antenna STC Matrix A", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit3",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit4,
			{
				"4-antenna STC Matrix B, vertical coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit4",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit5,
			{
				"4-antenna STC Matrix B, horizontal coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit5",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit6,
			{
				"4-antenna STC Matrix C, vertical coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit6",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit7,
			{
				"4-antenna STC Matrix C, horizontal coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit7",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit8,
			{
				"3-antenna STC Matrix A", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit8",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x100, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit9,
			{
				"3-antenna STC Matrix B", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit9",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x200, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit10,
			{
				"3-antenna STC Matrix C, vertical coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit10",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x400, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit11,
			{
				"3-antenna STC Matrix C, horizontal coding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit11",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x800, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit12,
			{
				"Capable Of Calculating Precoding Weight", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit12",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x1000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit13,
			{
				"Capable Of Adaptive Rate Control", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit13",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x2000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit14,
			{
				"Capable Of Calculating Channel Matrix", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit14",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x4000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit15,
			{
				"Capable Of Antenna Grouping", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit15",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x8000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit16,
			{
				"Capable Of Antenna Selection", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit16",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x10000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit17,
			{
				"Capable Of Codebook Based Precoding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit17",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x20000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit18,
			{
				"Capable Of Long-term Precoding", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit18",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x40000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_bit19,
			{
				"Capable Of MIMO Midamble", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.bit19",
				FT_BOOLEAN, 24, TFS(&tfs_supported), 0x80000, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_176_reserved,
			{
				"Reserved", "wmx.sbc.ofdma_ms_demodulator_for_mimo_support_in_dl.reserved",
				FT_UINT24, BASE_HEX, NULL, 0xF00000, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.18 */
			&hf_sbc_tlv_t_179_ofdma_multiple_dl_burst_profile_support,
			{
				"OFDMA Multiple Downlink Burst Profile Capability", "wmx.sbc.ofdma_multiple_dl_burst_profile_support",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_179_dl_bst_profile_for_multiple_fec,
			{
				"Downlink burst profile for multiple FEC types", "wmx.sbc.ofdma_multiple_dl_burst_profile_support.dl_bst_profile_for_multiple_fec",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_179_reserved,
			{
				"Reserved", "wmx.sbc.ofdma_multiple_dl_burst_profile_support.reserved",
				FT_UINT8, BASE_HEX, NULL, 0xFC, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_179_ul_bst_profile_for_multiple_fec,
			{
				"Uplink burst profile for multiple FEC types", "wmx.sbc.ofdma_multiple_dl_burst_profile_support.ul_burst_profile_for_multiple_fec_types",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.9 */
			&hf_sbc_ss_cinr_measure_capability,
			{
				"OFDMA SS CINR Measurement Capability", "wmx.sbc.ofdma_ss_cinr_measure_capability",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.6 */
			&hf_sbc_ss_mimo_uplink_support,
			{
				"OFDMA SS MIMO uplink support", "wmx.sbc.ofdma_ss_mimo_uplink_support",
				FT_UINT8, BASE_HEX, NULL, 0x00, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_mimo_uplink_support_2_ann_sttd,
			{
				"2-antenna STTD", "wmx.sbc.ofdma_ss_mimo_uplink_support.2_antenna_sttd",
				FT_UINT8, BASE_HEX, NULL, 0x01, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_mimo_uplink_support_2_ann_sm_vertical,
			{
				"2-antenna SM with vertical coding", "wmx.sbc.ofdma_ss_mimo_uplink_support.2_antenna_sm_with_vertical_coding",
				FT_UINT8, BASE_HEX, NULL, 0x02, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_mimo_uplink_support_1_ann_coop_sm,
			{
				"Single-antenna cooperative SM", "wmx.sbc.ofdma_ss_mimo_uplink_support.single_antenna_coop_sm",
				FT_UINT8, BASE_HEX, NULL, 0x04, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_ofdma_uplink_aas_preamble,
			{
				"Uplink AAS Preamble", "wmx.sbc.ofdma_uplink_aas_preamble",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_phy_cinr_measurement_preamble,
			{
				"Physical CINR Measurement From The Preamble", "wmx.sbc.phy_cinr_measure_preamble",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_pilot_subcarriers,
			{
				"Physical CINR Measurement For A Permutation Zone From Pilot Subcarriers", "wmx.sbc.phy_cinr_measure_permutation_zone.pilot_subcarriers",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_phy_cinr_measurement_permutation_zone_from_data_subcarriers,
			{
				"Physical CINR Measurement For A Permutation Zone From Data Subcarriers", "wmx.sbc.phy_cinr_measure_permutation_zone.data_subcarriers",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{	/* 11.7.8.6 */
			&hf_sbc_pkm_flow_control,
			{
				"PKM Flow Control", "wmx.sbc.pkm_flow_control",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{	/* 11.8.5 */
			&hf_sbc_power_save_class_types_capability,
			{
				"Power Save Class Types Capability", "wmx.sbc.power_save_class_types_capability",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_power_save_class_types_capability_bit0,
			{
				"Power Save Class Type I", "wmx.sbc.power_save_class_types_capability.bit0",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_power_save_class_types_capability_bit1,
			{
				"Power Save Class Type II", "wmx.sbc.power_save_class_types_capability.bit1",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_power_save_class_types_capability_bit2,
			{
				"Power Save Class Type III", "wmx.sbc.power_save_class_types_capability.bit2",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_power_save_class_types_capability_bits34,
			{
				"Number Of Power Save Class Type Instances Supported From Class Type I and II", "wmx.sbc.power_save_class_types_capability.bits34",
				FT_UINT8, BASE_DEC, NULL, 0x18, NULL, HFILL
			}
		},
		{
			&hf_sbc_power_save_class_types_capability_bits567,
			{
				"Number Of Power Save Class Type Instances Supported From Class Type III", "wmx.sbc.power_save_class_types_capability.bits567",
				FT_UINT8, BASE_DEC, NULL, 0xE0, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.7 */
			&hf_sbc_ofdma_aas_private_chain_enable,
			{
				"Private Map Chain Enable", "wmx.sbc.private_chain_enable",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_aas_private_map_concurrency,
			{
				"Private Map Chain Concurrency", "wmx.sbc.private_map_concurrency",
				FT_UINT8, BASE_HEX, NULL, 0xC0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_aas_private_map_dl_frame_offset,
			{
				"Private Map DL Frame Offset", "wmx.sbc.private_map_dl_frame_offset",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_aas_private_map_support,
			{
				"Private Map Support", "wmx.sbc.private_map_support",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_ofdma_aas_private,
			{
				"OFDMA AAS Private Map Support", "wmx.sbc.private_map_support.ofdma_aas",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_aas_reduced_private_map_support,
			{
				"Reduced Private Map Support", "wmx.sbc.private_map_support.reduced",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_aas_private_ul_frame_offset,
			{
				"Private Map UL Frame Offset", "wmx.sbc.private_ul_frame_offset",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_mac_pdu_rsvd,
			{
				"Reserved", "wmx.sbc.mac_pdu.rsvd",
				FT_UINT8, BASE_HEX, NULL, 0xFC, NULL, HFILL
			}
		},
		{	/* 11.8.3.2 */
			&hf_sbc_max_transmit_power,
			{
				"Maximum Transmit Power", "wmx.sbc.max_transmit_power",
				FT_UINT32, BASE_HEX, NULL, 0x00, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.5 - 2 bytes */
			&hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_a,
			{
				"2-antenna STC Matrix A", "wmx.sbc.ss_demodulator.mimo.2.antenna.stc.matrix.a",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_horizontal,
			{
				"2-antenna STC Matrix B, horizontal coding", "wmx.sbc.ss_demodulator.mimo.2.antenna.stc.matrix.b.horizontal",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_2_ann_stc_matrix_b_vertical,
			{
				"2-antenna STC Matrix B, vertical coding", "wmx.sbc.ss_demodulator.mimo.2.antenna.stc.matrix.b.vertical",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_a,
			{
				"4-antenna STC Matrix A", "wmx.sbc.ss_demodulator.mimo.4.antenna.stc.matrix.a",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_horizontal,
			{
				"4-antenna STC Matrix B, horizontal coding", "wmx.sbc.ss_demodulator.mimo.4.antenna.stc.matrix.b.horizontal",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_b_vertical,
			{
				"4-antenna STC Matrix B, vertical coding", "wmx.sbc.ss_demodulator.mimo.4.antenna.stc.matrix.b.vertical",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_horizontal,
			{
				"4-antenna STC Matrix C, horizontal coding", "wmx.sbc.ss_demodulator.mimo.4.antenna.stc.matrix.c.horizontal",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_4_ann_stc_matrix_c_vertical,
			{
				"4-antenna STC Matrix C, vertical coding", "wmx.sbc.ss_demodulator.mimo.4.antenna.stc.matrix.c.vertical",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_rsvd,
			{
				"Reserved", "wmx.sbc.ss_demodulator.mimo.reserved",
				FT_UINT16, BASE_HEX, NULL, 0xFF00, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_mimo_support,
			{
				"OFDMA SS Demodulator For MIMO Support", "wmx.sbc.ss_demodulator.mimo.support",
				FT_UINT16, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		/*11.8.3.7.11 ??? */
		{	/* 11.8.3.7.12 - 170 */
			&hf_sbc_ofdma_ss_uplink_power_control_support,
			{
				"OFDMA SS uplink power control support", "wmx.sbc.ofdma_ss_uplink_power_control_support",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_ss_uplink_power_control_support_open_loop,
			{
				"Open loop", "wmx.sbc.ofdma_ss_uplink_power_control_support.open_loop",
				FT_UINT8, BASE_HEX, NULL, 0x01, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_ss_uplink_power_control_support_aas_preamble,
			{
				"AAS preamble", "wmx.sbc.ofdma_ss_uplink_power_control_support.aas_preamble",
				FT_UINT8, BASE_HEX, NULL, 0x02, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdma_ss_uplink_power_control_support_rsvd,
			{
				"Reserved", "wmx.sbc.ofdma_ss_uplink_power_control_support.rsvd",
				FT_UINT8, BASE_HEX, NULL, 0xFC, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_172_dl_region_definition_support,
			{
				"DL Region Definition Support", "wmx.sbc.ofdma_map_capability.dl_region_definition_support",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.12 - 172 */
			&hf_sbc_tlv_t_172,
			{
				"Support For Extended HARQ", "wmx.sbc.ofdma_map_capability.extended_harq",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_172_extended_harq_ie_capability,
			{
				"Extended HARQ IE Capability", "wmx.sbc.ofdma_map_capability.extended_harq_ie_capability",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_172_harq_map_capability,
			{
				"HARQ MAP Capability", "wmx.sbc.ofdma_map_capability.harq_map_capability",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.12 - 171 */
			&hf_sbc_tlv_t_171_minimum_num_of_frames,
			{
				"The Minimum Number Of Frames That SS Takes To Switch From The Open Loop Power Control Scheme To The Closed Loop Power Control Scheme Or Vice Versa", "wmx.sbc.ofdma_ss_uplink_power_control_support.minimum_num_of_frames",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_172_reserved,
			{
				"Reserved", "wmx.sbc.ofdma_map_capability.reserved",
				FT_UINT8, BASE_HEX, NULL, 0xE0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_172_sub_map_capability_first_zone,
			{
				"Sub MAP Capability For First Zone", "wmx.sbc.ofdma_map_capability.sub_map_capability_first_zone",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_172_sub_map_capability_other_zones,
			{
				"Sub MAP Capability For Other Zones", "wmx.sbc.ofdma_map_capability.sub_map_capability_other_zones",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.14 */
			&hf_sbc_tlv_t_174_ofdma_ms_csit_capability,
			{
				"OFDMA MS CSIT Capability", "wmx.sbc.ofdma_ms_csit_capability",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_174_csit_compatibility_type_a,
			{
				"CSIT Compatibility Type A", "wmx.sbc.ofdma_ms_csit_capability.csit_compatibility_type_a",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_174_csit_compatibility_type_b,
			{
				"CSIT Compatibility Type B", "wmx.sbc.ofdma_ms_csit_capability.csit_compatibility_type_b",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_174_max_num_simultanous_sounding_instructions,
			{
				"Max Number Of Simultaneous Sounding Instructions", "wmx.sbc.ofdma_ms_csit_capability.max_num_simultaneous_sounding_instructions",
				FT_UINT16, BASE_DEC, NULL, 0x03C0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_174_power_assignment_capability,
			{
				"Power Assignment Capability", "wmx.sbc.ofdma_ms_csit_capability.power_assignment_capability",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_174_ss_csit_reserved,
			{
				"Reserved", "wmx.sbc.ofdma_ms_csit_capability.reserved",
				FT_UINT16, BASE_HEX, NULL, 0xF800, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_174_sounding_rsp_time_capability,
			{
				"Sounding Response Time Capability", "wmx.sbc.ofdma_ms_csit_capability.sounding_response_time_capability",
				FT_UINT16, BASE_HEX, VALS(vals_sounding_rsp_time_cap_codings), 0x0038, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_174_ss_csit_type_a_support,
			{
				"SS Does Not Support P Values Of 9 And 18 When Supporting CSIT Type A", "wmx.sbc.ofdma_ms_csit_capability.type_a_support",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x0400, NULL, HFILL
			}
		},
		{
			/* 11.8.3.7.20 */
			&hf_sbc_tlv_t_204_ofdma_parameters_sets,
			{
				"OFDMA parameters sets", "wmx.sbc.ofdma_parameters_sets",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_a,
			{
				"Support OFDMA PHY parameter set A", "wmx.sbc.ofdma_parameters_sets.phy_set_a",
				FT_UINT8, BASE_HEX, NULL, 0x01, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_204_ofdma_parameters_sets_phy_set_b,
			{
				"Support OFDMA PHY parameter set B", "wmx.sbc.ofdma_parameters_sets.phy_set_b",
				FT_UINT8, BASE_HEX, NULL, 0x02, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_204_ofdma_parameters_sets_harq_parameters_set,
			{
				"HARQ parameters set", "wmx.sbc.ofdma_parameters_sets.harq_parameters_set",
				FT_UINT8, BASE_HEX, VALS(vals_sbc_harq_parameters_set), 0x1C, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_a,
			{
				"Support OFDMA MAC parameters set A", "wmx.sbc.ofdma_parameters_sets.mac_set_a",
				FT_UINT8, BASE_HEX, NULL, 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_204_ofdma_parameters_sets_mac_set_b,
			{
				"Support OFDMA MAC parameters set B", "wmx.sbc.ofdma_parameters_sets.mac_set_b",
				FT_UINT8, BASE_HEX, NULL, 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_204_ofdma_parameters_sets_reserved,
			{
				"Reserved", "wmx.sbc.ofdma_parameters_sets.reserved",
				FT_UINT8, BASE_HEX, NULL, 0x80, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.16 */
			&hf_sbc_tlv_t_177_ofdma_ss_modulator_for_mimo_support,
			{
				"OFDMA SS Modulator For MIMO Support", "wmx.sbc.ofdma_ss_modulator_for_mimo_support",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_adaptive_rate_ctl,
			{
				"Capable Of Adaptive Rate Control", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.capable_adaptive_rate_control",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_beamforming,
			{
				"Capable Of Beamforming", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.capable_beamforming",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_single_antenna,
			{
				"Capable of single antenna transmission", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.capable_single_antenna",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_stc_matrix_b_horizontal,
			{
				"Capable of 2-antenna STC Matrix B, Horizontal coding", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.stc_matrix_b_horizontal",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_two_transmit_antennas,
			{
				"Two transmit antennas", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.two_transmit_antennas",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_capable_of_transmit_diversity,
			{
				"Capable of transmit diversity", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.capable_of_transmit_diversity",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_capable_of_spacial_multiplexing,
			{
				"Capable of spatial multiplexing", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.capable_of_spatial_multiplexing",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_stc_matrix_b_vertical,
			{
				"Capable of 2-antenna STC Matrix B, Vertical coding", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.stc_matrix_b_vertical",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_collaborative_sm_with_one_antenna,
			{
				"Capable of collaborative SM with one antenna", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.collaborative_sm_with_one_antenna",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_collaborative_sm_with_two_antennas,
			{
				"Collaborative SM with two antennas", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.collaborative_sm_with_two_antennas",
				FT_UINT8, BASE_HEX, NULL, 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_capable_of_two_antenna,
			{
				"Capable of two antenna", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.capable_of_two_antenna",
				FT_UINT8, BASE_HEX, NULL, 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_rsvd,
			{
				"Reserved", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.rsvd",
				FT_UINT8, BASE_HEX, NULL, 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_177_stc_matrix_a,
			{
				"Capable of 2-antenna STC Matrix A", "wmx.sbc.ofdma_ss_modulator_for_mimo_support.stc_matrix_a",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.17 */
			&hf_sbc_tlv_t_178_sdma_pilot_capability,
			{
				"SDMA Pilot Capability", "wmx.sbc.sdma_pilot_capability",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_178_reserved,
			{
				"Reserved", "wmx.sbc.sdma_pilot_capability.reserved",
				FT_UINT8, BASE_HEX, NULL, 0xFC, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_178_sdma_pilot_pattern_support_for_amc_zone,
			{
				"SDMA Pilot Patterns Support For AMC Zone", "wmx.sbc.sdma_pilot_capability.sdma_pilot_pattern_support_for_amc_zone",
				FT_UINT8, BASE_HEX, VALS(vals_sbc_sdma_str), 0x03, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.2 - type 151 */
			&hf_sbc_ss_demodulator,
			{
				"OFDMA SS Demodulator", "wmx.sbc.ss_demodulator",
				FT_BYTES, BASE_NONE, NULL, 0x0, NULL, HFILL
			}
		},
		/* tlv length = 1 byte */
		{
			&hf_sbc_ss_demodulator_64qam,
			{
				"64-QAM", "wmx.sbc.ss_demodulator.64qam",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_btc,
			{
				"BTC", "wmx.sbc.ss_demodulator.btc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_cc_with_optional_interleaver,
			{
				"CC with Optional Interleaver", "wmx.sbc.ss_demodulator.cc_with_optional_interleaver",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_ctc,
			{
				"CTC", "wmx.sbc.ss_demodulator.ctc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		/* tlv length = 2 bytes */
		{
			&hf_sbc_ss_demodulator_64qam_2,
			{
				"64-QAM", "wmx.sbc.ss_demodulator.64qam",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_btc_2,
			{
				"BTC", "wmx.sbc.ss_demodulator.btc",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_cc_with_optional_interleaver_2,
			{
				"CC with Optional Interleaver", "wmx.sbc.ss_demodulator.cc_with_optional_interleaver",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_ctc_2,
			{
				"CTC", "wmx.sbc.ss_demodulator.ctc",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_dedicated_pilots_2,
			{
				"Dedicated Pilots", "wmx.sbc.ss_demodulator.dedicated_pilots",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x400, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_harq_cc_ir_2,
			{
				"HARQ CC_IR", "wmx.sbc.ss_demodulator.harq.cc.ir",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x100, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_harq_chase,
			{
				"HARQ Chase", "wmx.sbc.ss_demodulator.harq.chase",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_harq_chase_2,
			{
				"HARQ Chase", "wmx.sbc.ss_demodulator.harq.chase",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_harq_ctc_ir,
			{
				"HARQ CTC_IR", "wmx.sbc.ss_demodulator.harq.ctc.ir",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_harq_ctc_ir_2,
			{
				"HARQ CTC_IR", "wmx.sbc.ss_demodulator.harq.ctc.ir",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_ldpc_2,
			{
				"LDPC", "wmx.sbc.ss_demodulator.ldpc",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x200, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_reserved,
			{
				"Reserved", "wmx.sbc.ss_demodulator.reserved1",
				FT_UINT8, BASE_HEX, NULL, 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_reserved_2,
			{
				"Reserved", "wmx.sbc.ss_demodulator.reserved2",
				FT_UINT16, BASE_HEX, NULL, 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_reserved1_2,
			{
				"Reserved", "wmx.sbc.ss_demodulator.reserved2",
				FT_UINT16, BASE_HEX, NULL, 0x800, NULL, HFILL
			}
		},
		{	/* if the number of DL H-ARQ channels > 7 but tlv length = 1 */
			&hf_sbc_ss_demodulator_reserved1,
			{
				"Reserved", "wmx.sbc.ss_demodulator.reserved1",
				FT_UINT16, BASE_HEX, NULL, 0xFFFF, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_stc,
			{
				"STC", "wmx.sbc.ss_demodulator.stc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_demodulator_stc_2,
			{
				"STC", "wmx.sbc.ss_demodulator.stc",
				FT_BOOLEAN, 16, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
	/* 11.8.3.4 - 11.8.3.6 are not supported for now */
		{	/* 11.8.3.7.1 */
			&hf_sbc_ss_fft_sizes,
			{
				"OFDMA SS FFT Sizes", "wmx.sbc.ss_fft_sizes",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
			{
			&hf_sbc_ss_fft_128,
			{
				"FFT-128", "wmx.sbc.ss_fft_sizes.128",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_fft_256,
			{
				"FFT-256", "wmx.sbc.ss_fft_sizes.256",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_fft_512,
			{
				"FFT-512", "wmx.sbc.ss_fft_sizes.512",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_fft_1024,
			{
				"FFT-1024", "wmx.sbc.ss_fft_sizes.1024",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_fft_2048,
			{
				"FFT-2048", "wmx.sbc.ss_fft_sizes.2048",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_fft_rsvd1,
			{
				"Reserved", "wmx.sbc_ss_fft_sizes_rsvd1",
				FT_UINT8, BASE_HEX, NULL, 0x01, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_fft_rsvd2,
			{
				"Reserved", "wmx.sbc.ss_fft_sizes.rsvd2",
				FT_UINT8, BASE_HEX, NULL, 0xE0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ofdm_ss_minimum_num_of_frames,
			{
				"SS minimum number of frames", "wmx.sbc.ss_minimum_num_of_frames",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_mimo_uplink_support_rsvd,
			{
				"Reserved", "wmx.sbc.ss_mimo_ul_support.rsvd",
				FT_UINT8, BASE_HEX, NULL, 0xF8, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.3 - type 152 */
			&hf_sbc_ss_modulator,
			{
				"OFDMA SS Modulator", "wmx.sbc.ss_modulator",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_64qam,
			{
				"64-QAM", "wmx.sbc.ss_modulator.64qam",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_btc,
			{
				"BTC", "wmx.sbc.ss_modulator.btc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_cc_ir,
			{
				"CC_IR", "wmx.sbc.ss_modulator.cc_ir",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_ctc,
			{
				"CTC", "wmx.sbc.ss_modulator.ctc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_ctc_ir,
			{
				"CTC_IR", "wmx.sbc.ss_modulator.ctc_ir",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_harq_chase,
			{
				"HARQ Chase", "wmx.sbc.ss_modulator.harq_chase",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_ldpc,
			{
				"LDPC", "wmx.sbc.ss_modulator.ldpc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_modulator_stc,
			{
				"STC", "wmx.sbc.ss_modulator.stc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.4 */
			&hf_sbc_ss_permutation_support,
			{
				"OFMDA SS Permutation Support", "wmx.sbc.ss_permutation_support",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_amc_1x6,
			{
				"AMC 1x6", "wmx.sbc.ss_permutation_support.amc_1x6",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_amc_2x3,
			{
				"AMC 2x3", "wmx.sbc.ss_permutation_support.amc_2x3",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_amc_3x2,
			{
				"AMC 3x2", "wmx.sbc.ss_permutation_support.amc_3x2",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_amc_with_harq_map,
			{
				"AMC Support With H-ARQ Map", "wmx.sbc.ss_permutation_support.amc_support_harq_map",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_optimal_fusc,
			{
				"Optional FUSC", "wmx.sbc.ss_permutation_support.optimal_fusc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_optimal_pusc,
			{
				"Optional PUSC", "wmx.sbc.ss_permutation_support.optimal_pusc",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_tusc1_support,
			{
				"TUSC1", "wmx.sbc.ss_permutation_support.tusc1_support",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_tusc2_support,
			{
				"TUSC2", "wmx.sbc.ss_permutation_support.tusc2_support",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_ssrtg,
			{
				"SSRTG", "wmx.sbc.ssrtg",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ssttg,
			{
				"SSTTG", "wmx.sbc.ssttg",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_ss_support_2_concurrent_cqi_channels,
			{
				"Support for 2 Concurrent CQI Channels", "wmx.sbc.support_2_concurrent_cqi_channels",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{	/* 11.8.3.1 */
			&hf_sbc_transition_gaps,
			{
				"Subscriber Transition Gaps", "wmx.sbc.transition_gaps",
				FT_UINT16, BASE_HEX, NULL, 0x00, NULL, HFILL
			}
		},
		{	/* 11.8.3.7.13 */
			&hf_sbc_tlv_t_173_ul_ctl_channel_support,
			{
				"Uplink Control Channel Support", "wmx.sbc.ul_ctl_channel_support",
				FT_UINT8, BASE_HEX, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_3_bit_mimo_fast_feedback,
			{
				"3-bit MIMO Fast-feedback", "wmx.sbc.ul_ctl_channel_support.3bit_mimo_fast_feedback",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x1, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_diuc_cqi_fast_feedback,
			{
				"DIUC-CQI Fast-feedback", "wmx.sbc.ul_ctl_channel_support.diuc_cqi_fast_feedback",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x80, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_enhanced_fast_feedback,
			{
				"Enhanced Fast_feedback", "wmx.sbc.ul_ctl_channel_support.enhanced_fast_feedback",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x2, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_measurement_report,
			{
				"A Measurement Report Shall Be Performed On The Last DL Burst", "wmx.sbc.ul_ctl_channel_support.measurement_report",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x20, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_primary_secondary_fast_feedback,
			{
				"Primary/Secondary FAST_FEEDBACK", "wmx.sbc.ul_ctl_channel_support.primary_secondary_fast_feedback",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x40, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_reserved,
			{
				"Reserved", "wmx.sbc.ul_ctl_channel_support.reserved",
				FT_UINT8, BASE_HEX, NULL, 0x8, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_uep_fast_feedback,
			{
				"UEP Fast-feedback", "wmx.sbc.ul_ctl_channel_support.uep_fast_feedback",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x10, NULL, HFILL
			}
		},
		{
			&hf_sbc_tlv_t_173_ul_ack,
			{
				"UL ACK", "wmx.sbc.ul_ctl_channel_support.ul_ack",
				FT_BOOLEAN, 8, TFS(&tfs_supported), 0x4, NULL, HFILL
			}
		},
		{
			&hf_sbc_req_message_type,
			{
				"MAC Management Message Type", "wmx.macmgtmsgtype.sbc_req",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{	&hf_sbc_rsp_message_type,
			{
				"MAC Management Message Type", "wmx.macmgtmsgtype.sbc_rsp",
				FT_UINT8, BASE_DEC, NULL, 0x0, NULL, HFILL
			}
		},
		{
			&hf_sbc_unknown_type,
			{
				"Unknown SBC type", "wmx.sbc.unknown_tlv_type",
				FT_BYTES, BASE_NONE, NULL, 0x0, NULL, HFILL
			}
		}
	};

	/* Setup protocol subtree array */
	static gint *ett_sbc[] =
		{
			&ett_mac_mgmt_msg_sbc_decoder,
			&ett_sbc_req_tlv_subtree,
			&ett_sbc_rsp_tlv_subtree,
		};

	proto_mac_mgmt_msg_sbc_decoder = proto_register_protocol (
		"WiMax SBC-REQ/RSP Messages", /* name       */
		"WiMax SBC-REQ/RSP (sbc)",    /* short name */
		"wmx.sbc"                     /* abbrev     */
		);

	proto_register_field_array(proto_mac_mgmt_msg_sbc_decoder, hf_sbc, array_length(hf_sbc));
	proto_register_subtree_array(ett_sbc, array_length(ett_sbc));
}