HUAWEI-NGADSL-LINE-MIB: View SNMP OID List / Download MIB

The actual value of Coding gain upstream parameter,it ranges from 0 to 16. Unit: 0.5 dB

The actual value of Coding gain downstream parameter,it ranges from 0 to 16. Unit: 0.5 dB

Indicates Power Cut-back on downstream direction. It ranges from 0 to 400 units of 0.1 dB (physical values are 0 to 40 dB). Unit: tenth dB

Indicates Power Cut-back on upstream direction. It ranges from 0 to 400 units of 0.1 dB (physical values are 0 to 40 dB) Unit: tenth dB

The value of this object identifies the row in the ADSL Dynamic Profile Table,which applies to this ADSL line, and channels if applicable. NULL - indicates that there is no Dynamic profile bound to this port.

The actual impulse noise protection (INP) on the bearer channel in L0 state. Unit: 0.1 DMT symbol

The actual number of Reed-Solomon redundancy bytes per codeword used in the latency path in which the bearer channel is transported. The value is coded in bytes. The value 0 indicates no Reed-Solomon coding. Unit: byte

The DMT Symbol number per codeword used in the latency path in which the bearer channel is transported. Unit: 0.01 DMT symbol

The actual Reed-Solomon codeword size used in the latency path in which the bearer channel is transported. The value ranges from 1 to 4096 by step of 1. The value 1 indicates no interleaving.

The actual number of bits per symbol assigned to the latency path in which the bearer channel is transported. This value does not include trellis overhead. Unit: bit

The actual Reed-Solomon codeword size used in the latency path in which the bearer channel is transported. Unit: byte

The PSD MASK per sub-carrier.An array of 512 16-bits values, designed for supporting up to 512 (downstream) sub-carriers. It ranges from -1400 to -300 units of 0.1 dBm/Hz (physical values are -140 to -30 dBm/Hz) Unit: 0.1 dBm/Hz

SNR Margin is the maximum increase in dB of the noise power received at the ATU (ATU-R on downstream direction and ATU-C on upstream direction), such that the BER requirements are met for all bearer channels received at the ATU. It ranges from -640 to 630 units of 0.1 dB (physical values are -64 to 63 dB). Unit: 0.1 dB

Count of seconds since agent reset that there was at least one FEC correction event for one or more bearer channels in this line. This parameter is inhibited during UAS or SES. Unit: seconds

Count of seconds since agent reset that there was: ATU-C: CRC-8 >= 1 for one or more bearer channels OR LOS >= 1 OR SEF >= 1 OR LPR >= 1 ATU-R: FEBE >= 1 for one or more bearer channels OR LOS-FE >= 1 OR RDI >= 1 OR LPR-FE >= 1. This parameter is inhibited during UAS. Unit: seconds

Count of seconds since agent reset that there was: ATU-C: (CRC-8 summed over all bearer channels) >= 18 OR LOS >= 1 OR SEF >= 1 OR LPR >= 1 ATU-R: (FEBE summed over all bearer channels) >= 18 OR LOS-FE >= 1 OR RDI >= 1 OR LPR-FE >= 1 This parameter is inhibited during UAS. Unit: seconds

Count of seconds since agent reset that there was LOS (or LOS-FE for ATU-R). Unit: seconds

Count of seconds in Unavailability State since agent reset. Unavailability begins at the onset of 10 contiguous severely -errored seconds, and ends at the onset of 10 contiguous seconds with no severely-errored seconds. Unit: seconds

Count of full initializations attempted on the line (successful and failed) since agent reset.

Count of failed full initializations on the line since agent reset.

Count of short initializations attempted on the line (successful and failed) since agent reset.

Count of failed short initializations on the line since agent reset.

Count of CRC-8 (FEBE for ATU-R) anomalies occurring in the channel since agent reset. This parameter is inhibited during UAS or SES. If the CRC is applied over multiple channels, then each related CRC-8 (or FEBE) anomaly should increment each of the counters related to the individual channels.

Count of FEC (FFEC for ATU-R) anomalies (corrected code words) occurring in the channel since agent reset. This parameter is inhibited during UAS or SES. If the FEC is applied over multiple channels, then each related FEC (or FFEC) anomaly should increment each of the counters related to the individual channels.

Enable and disable the trellis mode. This object is defaulted enabled(2). Options: 1. disable(1) - Disable the trellis 2. enable(2) - Enable the trellis

Enable and disable the bit swap downstream of a line. This object is defaulted enable(2). Options: 1. disable(1) - Disable the bit swap downstream of a line 2. enable(2) - Enable the bit swap downstream of a line

Enable and disable the bit swap upstream of a line. This object is defaulted enable(2). Options: 1. disable(1) - Disable the bit swap upstream of a line 2. enable(2) - Enable the bit swap upstream of a line

This parameter defines the PSD mask that is assumed to be permitted at the exchange. This parameter shall use the same format as PSDMASKds.The maximum number of breakpoints for DPBOEPSD is 16. This is a string of 16 pairs of values in the following structure: Octets 0+1 - Index of 1st sub-carrier used in the context of a first breakpoint Octet 2 - The PSD reduction for the sub-carrier indicated in octets 0 and 1 Octets 3-5 - Same, for a 2nd breakpoint Octets 6-8 - Same, for a 3rd breakpoint This architecture continues until octets 45-47, which are associated with a 16th breakpoint. Each subcarrier index is an unsigned number in the range 1 and NSCds. Each PSD reduction value is in the range 0 (0dBm/Hz) to 255 (-127.5dBm/Hz) with steps of 0.5dBm/Hz. Valid values are in the range 0 to 190 (0 to -95dBm/Hz). When the number of breakpoints is less than 16, all remaining octets are set to the value 0xff. Unit: 0.5dBm/Hz

This configuration parameter defines the assumed electrical length of cables (E-side cables) connecting exchange based DSL services to a remote flexibility point (cabinet), that hosts the xTU-C that is subject to spectrally shaped downstream power back-off depending on this length. For this parameter the electrical length is defined as the loss (in dB) of an equivalent length of hypothetical cable at a reference frequency defined by the network operator or in spectrum management regulations. DPBOESEL shall be coded as an unsigned integer representing an electrical length from 0 dB (coded as 0) to 255.5 dB (coded as 511) in steps of 0.5 dB. All values in the range are valid.If DPBOESEL is set to zero, the DPBO in this section shall be disabled. This object is defaulted 0. Unit: 0.5dB

This configuration parameter defines a cable model in terms of three scalars DPBOESCMA, DPBOESCMB and DPBOESCMC that shall be used to describe the frequency dependent loss of E-side cables.Parameters DPBOESCMA, DPBOESCMB, DPBOESCMC shall be coded as unsigned integers representing a scalar value from -1 (coded as 0) to 1.5 (coded as 640) in step of 1/256. All values in the range are valid. This object is defaulted 256.

This configuration parameter defines a cable model in terms of three scalars DPBOESCMA, DPBOESCMB and DPBOESCMC that shall be used to describe the frequency dependent loss of E-side cables.Parameters DPBOESCMA, DPBOESCMB, DPBOESCMC shall be coded as unsigned integers representing a scalar value from -1 (coded as 0) to 1.5 (coded as 640) in step of 1/256. All values in the range are valid.This object is defaulted 512.

This configuration parameter defines a cable model in terms of three scalars DPBOESCMA, DPBOESCMB and DPBOESCMC that shall be used to describe the frequency dependent loss of E-side cables.Parameters DPBOESCMA, DPBOESCMB, DPBOESCMC shall be coded as unsigned integers representing a scalar value from -1 (coded as 0) to 1.5 (coded as 640) in step of 1/256. All values in the range are valid.This object is defaulted 256.

DPBOMUS defines the assumed Minimum Usable receive Signal PSD (in dBm/Hz) for exchange based services, used to modify parameter DPBOFMAX defined below. It shall be coded as an unsigned integer representing a PSD level from 0 dBm/Hz (coded as 0) to -127.5 dBm/Hz (coded as 255) in steps of 0.5 dBm/Hz. All values in the range are valid.This object is defaulted 180. Unit: 0.5dBm/Hz

DPBOFMIN defines the minimum frequency from which the DPBO shall be applied. It shall be coded as a 16 bits unsigned integer representing a frequency in multiple of 4.3125 KHz. The range of valid values is from 0 kHz (coded as 0) to 8832 kHz (coded as 2048). This object is defaulted 0. Unit: 4.3125 KHz

DPBOFMAX defines the maximum frequency at which DPBO may be applied. It shall be coded as a 16 bits unsigned integer representing a frequency in multiple of 4.3125 KHz. The range of valid values is from 138 kHz (coded as 32) to 29997.75 kHz (coded as 6956). This object is defaulted 511. Unit: 4.3125 KHz

The channel monitoring rate downstream. When the value you set is larger than the value of the rate downstream defined in the channel profile, it will not be successful. The value 0 means that no threshold is specified for the associated counter. This object is defaulted 0. Unit: bits/second

The channel monitoring rate upstream. When the value you set is larger than the value of the rate upstream defined in the channel profile, it will not be successful. The value 0 means that no threshold is specified for the associated counter. This object is defaulted 0. Unit: bits/second

This object is used to change ADSL management mode. After the mode being changed, system will automatically save data and reboot. Options: 1. rfc2662(1) - Management model based on RFC2662 and RFC3440 2. rfc4706(2) - Management model based on RFC4706 3. tr165(3) - Management model based on TR-165

This object is used to change abr-calculation mode. Options: 1. normalMode(1) - Change mode to normal abr-calculation 2. ptMode(2) - Change mode to pt abr-calculation Enumeration: 'ptMode': 2, 'normalMode': 1.

The MIB is used for defining HUAWEI NGADSL LINE MIB objects, which expand from RFC4706 ADSL2-LINE MIB.

The table hwadsl2LineTable contains configuration, command, and status parameters of the ADSL2 line. The index of this table is an interface index where the interface has an ifType of adsl2plus(238). Several objects in this table MUST be maintained in a persistent manner.

The table hwadsl2LineTable contains configuration, command, and status parameters of the ADSL2 line. The index of this entry is an interface index where the interface has an ifType of adsl2plus(238). Several objects in this table MUST be maintained in a persistent manner.

The actual value of Coding gain upstream parameter,it ranges from 0 to 16 units of 0.5 dB. Unit: 0.5 dB

The actual value of Coding gain downstream parameter,it ranges from 0 to 16 units of 0.5 dB. Unit: 0.5 dB

Indicates Power Cut-back on downstream direction. It ranges from 0 to 400 units of 0.1 dB (physical values are 0 to 40 dB). Unit: tenth dB

Indicates Power Cut-back on upstream direction. It ranges from 0 to 400 units of 0.1 dB (physical values are 0 to 40 dB) and the invalid value is 4294967295. Unit: tenth dB

The value of this object identifies the row in the ADSL Dynamic Profile Table,which applies to this ADSL line, and channels if applicable. NULL -Indicates that there is no Dynamic profile bound to this port.

Indicates the result of the last full initialization performed on the line. Options: 1. noFail(0) - Successful initialization 2. configError(1) - Configuration failure 3. configNotFeasible(2) - Configuration details not supported 4. commFail(3) - Communication failure 5. noPeerXtu(4) - Peer xTU not detected 6. otherCause(5) - Other initialization failure reason 7. ginpNotSelected(6) - G.998.4 Retransmission mode was not selected while RTX_MODE = FORCED or with RTX_MODE = RTX_TESTMODE 8. invalidValue(-1) - Invalid value

This parameter specifies whether G.998.4 retransmission is used in a given transmit direction. Options: 1. rtxInuse(1) - RTX in use 2. rtxUnusedModeForbidden(2) - RTX not in use, due to RTX_MODE = FORBIDDEN 3. rtxUnusedNotSupportedXtuc(3) - RTX not in use, due to not supported by the XTU-C 4. rtxUnusedNotSupportedXtur(4) - RTX not in use, due to not supported by the XTU-R 5. rtxUnusedNotSupportedXtucAndXtur(5) - RTX not in use, due to not supported by the XTU-C and XTU-R 6. invalidValue(-1) - Invalid value

Indicates the last retrained information performed on the line. Options: 1. none(1) - No record is available 2. cpe-l3-trigger(2) - The terminal initiates a low power consumption L3 request 3. lom-us-trigger-dra(3) - The upstream noise margin is smaller than the minimum noise margin in rate dynamic adjustment 4. lom-ds-trigger-dra(4) - The downstream noise margin is smaller than the minimum noise margin in rate dynamic adjustment 5. cpe-never-answer-oam(5) - No OAM response is received from the CPE all the time 6. cpe-no-more-answer-oam(6) - No OAM response is received from the CPE 7. persistent-ncd-us(7) - Upstream continuous no cell delineation 8. persistent-ncd-ds(8) - Downstream continuous no cell delineation 9. persistent-lcd-us(9) - Upstream continuous loss of cell delineation 10.persistent-lcd-ds(10) - Downstream continuous loss of cell delineation 11.l2-problem-co-drop(11) - The CO is faulty during the switching from L0 to L2 12.l2-problem-cpe-drop(12) - The CPE is faulty during the switching from L0 to L2 13.bitswap-refused-us-co-drop(13) - The CO goes offline when the upstream bit swap fault occurs 10 times consecutively 14.bitswap-refused-us-cpe-drop(14) - The CPE goes offline when the downstream bit swap fault occurs 10 times consecutively 15.channel-change-us-co-drop(15) - The CO goes offline when the upstream net rate changes 16.channel-change-us-cpe-drop(16) - The CPE goes offline when the upstream net rate changes 17.noise-increase-us-co-drop(17) - The CO goes offline when the upstream noise increases 18.noise-increase-us-cpe-drop(18) - The CPE goes offline when the upstream noise increases 19.bitswap-refused-ds-co-drop(19) - The CO goes offline when the downstream bit swap fault occurs 10 times consecutively 20.bitswap-refused-ds-cpe-drop(20) - The CPE goes offline when the downstream bit swap fault occurs 10 times consecutively 21.channel-change-ds-co-drop(21) - The CO goes offline when the downstream net rate changes 22.channel-change-ds-cpe-drop(22) - The CPE goes offline when the downstream net rate changes 23.noise-increase-ds-co-drop(23) - The CO goes offline when the downstream noise increases 24.noise-increase-ds-cpe-drop(24) - The CPE goes offline when the downstream noise increases 25.lom-us-co-drop(25) - The CO goes offline when the upstream noise margin is smaller than the minimum noise margin 26.lom-us-cpe-drop(26) - The CPE goes offline when the upstream noise margin is smaller than the minimum noise margin 27.lom-ds-co-drop(27) - The CO goes offline when the downstream noise margin is smaller than the minimum noise margin 28.lom-ds-cpe-drop(28) - The CPE goes offline when the downstream noise margin is smaller than the minimum noise margin 29.sra-problem-us-co-drop(29) - The CO goes offline when the upstream SRA is faulty 30.sra-problem-us-cpe-drop(30) - The CPE goes offline when the upstream SRA is faulty 31.sra-failed-us-co-drop(31) - The CO goes offline when the upstream SRA fails 32.sra-failed-us-cpe-drop(32) - The CPE goes offline when the upstream SRA fails 33.sra-problem-ds-co-drop(33) - The CO goes offline when the downstream SRA is fault 34.sra-problem-ds-cpe-drop(34) - The CPE goes offline when the downstream SRA is faulty 35.sra-rejected-ds-co-drop(35) - The CO goes offline when the downstream SRA is rejected 36.sra-rejected-ds-cpe-drop(36) - The CPE goes offline when the downstream SRA is rejected 37.bitswap-problem-us-co-drop(37) - The CO goes offline when the upstream bit swap is faulty 38.bitswap-problem-us-cpe-drop(38) - The CPE goes offline when the upstream bit swap is faulty 39.bitswap-failed-us-co-drop(39) - The CO goes offline when the upstream bit swap fails 40.bitswap-failed-us-cpe-drop(40) - The CPE goes offline when the upstream bit swap fails 41.bitswap-problem-ds-co-drop(41) - The CO goes offline when the downstream bit swap is faulty 42.bitswap-problem-ds-cpe-drop(42) - The CPE goes offline when the downstream bit swap is faulty 43.bitswap-rejected-ds-co-drop(43) - The CO goes offline when the downstream bit swap is rejected 44.bitswap-rejected-ds-cpe-drop(44) - The CPE goes offline when the downstream bit swap is rejected 45.cpe-switched-off(45) - The CPE power supply is shut down 46.cpe-lost(46) - The CPE is disconnected 47.co-reset(47) - The CO resets the chipset or line 48.co-stop(48) - The CO actively deactivate the port 49.unknown(49) - Unknown reason Enumeration: 'sra-rejected-ds-co-drop': 35, 'persistent-ncd-ds': 8, 'sra-problem-ds-cpe-drop': 34, 'bitswap-failed-us-cpe-drop': 40, 'lom-us-cpe-drop': 26, 'bitswap-refused-ds-co-drop': 19, 'lom-ds-cpe-drop': 28, 'bitswap-problem-us-co-drop': 37, 'channel-change-us-cpe-drop': 16, 'cpe-lost': 46, 'l2-problem-cpe-drop': 12, 'channel-change-ds-cpe-drop': 22, 'cpe-switched-off': 45, 'sra-failed-us-co-drop': 31, 'persistent-lcd-us': 9, 'unknown': 49, 'l2-problem-co-drop': 11, 'bitswap-rejected-ds-co-drop': 43, 'bitswap-failed-us-co-drop': 39, 'lom-ds-co-drop': 27, 'persistent-lcd-ds': 10, 'sra-problem-us-co-drop': 29, 'noise-increase-us-cpe-drop': 18, 'noise-increase-ds-cpe-drop': 24, 'sra-problem-ds-co-drop': 33, 'bitswap-refused-us-cpe-drop': 14, 'persistent-ncd-us': 7, 'bitswap-refused-us-co-drop': 13, 'noise-increase-ds-co-drop': 23, 'channel-change-ds-co-drop': 21, 'co-reset': 47, 'cpe-no-more-answer-oam': 6, 'channel-change-us-co-drop': 15, 'lom-ds-trigger-dra': 4, 'bitswap-problem-ds-co-drop': 41, 'none': 1, 'cpe-l3-trigger': 2, 'noise-increase-us-co-drop': 17, 'sra-problem-us-cpe-drop': 30, 'lom-us-co-drop': 25, 'bitswap-problem-us-cpe-drop': 38, 'sra-failed-us-cpe-drop': 32, 'cpe-never-answer-oam': 5, 'co-stop': 48, 'sra-rejected-ds-cpe-drop': 36, 'bitswap-problem-ds-cpe-drop': 42, 'lom-us-trigger-dra': 3, 'bitswap-rejected-ds-cpe-drop': 44, 'bitswap-refused-ds-cpe-drop': 20.

The actual line rate downstream. Unit: bits/second

The actual line rate upstream. Unit: bits/second

The table hwadsl2ChannelStatusTable contains status parameters of the ADSL2 channel and live data from equipment. The indexes of this table are ifIndex and adsl2ChStatusUnit.

The table hwadsl2ChannelStatusTable contains status parameters of the ADSL2 channel and live data from equipment. The indexes of this entry are ifIndex and adsl2ChStatusUnit.

The bits in the channel that used to retransmission. Unit: bit

The number of the units for retransmission.

If retransmission is not used in a given transmit direction, this parameter reports the actual impulse noise protection (INP) on the bearer channel in the L0 state. In the L1 or L2 state, the parameter contains the INP in the previous L0 state. If retransmission is used in a given transmit direction, this parameter reports the actual impulse noise protection (INP) against SHINE on the bearer channel in the L0 state. In the L2 state, the parameter contains the INP in the previous L0 state. Unit: 0.1 DMT symbol

The actual number of Reed-Solomon redundancy bytes per codeword used in the latency path in which the bearer channel is transported. The value is coded in bytes. The value 0 indicates no Reed-Solomon coding. Unit: byte

The DMT Symbol number per codeword used in the latency path in which the bearer channel is transported. Unit: 0.01 DMT symbol

The actual Reed-Solomon codeword size used in the latency path in which the bearer channel is transported. The value ranges from 1 to 4096 by step of 1. The value 1 indicates no interleaving.

The actual number of bits per symbol assigned to the latency path in which the bearer channel is transported. This value does not include trellis overhead. Unit: bit

The actual Reed-Solomon codeword size used in the latency path in which the bearer channel is transported. Unit: byte

In L0 state, this parameter reports the Net Data Rate at which the bearer channel is operating. In L2 state, this parameter contains the Net Data Rate in the previous L0 state. This parameter is optional if G.998.4 retransmission function is not supported. The data rate is coded in steps of 1000 bit/s.

If retransmission is used in a given transmit direction, this parameter reports the actual impulse noise protection (INP) against REIN (under specific conditions detailed in G.998.4) on the bearer channel in the L0 state. In the L2 state, the parameter contains the INP in the previous L0 state. The value is coded in fractions of DMT symbols with a granularity of 0.1 symbols.

The table hwadsl2SCStatusTable contains status parameters of the ADSL2 sub-carriers. The following points apply to this table: 1. The main purpose of this table is to hold the results of a DELT. 2. This table also holds parameters obtained at line initialization time. 3. The rows in this table are volatile; that is, they are lost if the SNMP agent is rebooted. 4. Due to the large OCTET STRING attributes in this table, the worst case memory requirements for this table are very high. The manager may use the row status attribute of this table to delete rows in order to reclaim memory. 5. The manager may create rows in this table. The SNMP agent may create rows in this table. Only the manager may delete rows in this table. 6. The maximum number of rows allowable in this table is indicated by the scalar attribute adsl2ScalarSCMaxInterfaces. The number of rows available in this table is indicated by the scalar attribute adsl2ScalarSCAvailInterfaces. 7. The SNMP agent is permitted to create rows in this table when a DELT completes successfully or when line initialization occurs. It is not mandatory for the SNMP agent to create rows in this table; hence, it may be necessary for the manager to create rows in this table before any results can be stored. 8. If the manager attempts to create a row in this table and there are no more rows available, the creation attempt will fail, and the response to the SNMP SET PDU will contain the error noCreation(11). 9. If the SNMP agent attempts to create a row in this table and there are no more rows available, the creation attempt will fail, and the attribute adsl2LineCmndConfLdsfFailReason will indicate the reason for the failure. The failure reason will be either tableFull(10) or noResources(11). 10. An example of use of this table is as follows: Step 1. : The DELT is started by setting the : adsl2LineCmndConfLdsf from inhibit to force. Step 2. : The DELT completes, and valid data is : available. Step 3. : The row in the adsl2SCStatusTable where the : results will be stored does not yet exist so : the SNMP agent attempts to create the row. Step 4. : Due to a low memory condition, a row in the : adsl2SCStatusTable table cannot be created at : this time. Step 5. : The reason for the failure, tableFull(10), is : indicated in the adsl2LineCmndConfLdsfFailReason : attribute. 11. Another example of use of this table is as follows : Step 1. : The DELT is started by setting the : adsl2LineCmndConfLdsf from inhibit to force. Step 2. : The DELT completes and valid data is : available. Step 3. : The row in the adsl2SCStatusTable where the : results will be stored does not yet exist so : the SNMP agent attempts to create the row. Step 4. : The row creation is successful. Step 5. : The value of the attribute : adsl2LineCmndConfLdsfFailReasonreason is set : to success(2). 12. Another example of use of this table is as follows: Step 1. : The manager creates a row in adsl2SCStatusTable : for a particular ADSL2 line. Step 2. : The DELT is started on the above-mentioned : line by setting the adsl2LineCmndConfLdsf from : inhibit to force. Step 3. : The DELT completes, and valid data is : available. Step 4. : The value of the attribute : adsl2LineCmndConfLdsfFailReasonreason is set : to success(2). The indexes of this table are ifIndex and adsl2SCStatusDirection.

The table hwadsl2SCStatusTable contains status parameters of the ADSL2 sub-carriers. The following points apply to this table: 1. The main purpose of this table is to hold the results of a DELT. 2. This table also holds parameters obtained at line initialization time. 3. The rows in this table are volatile; that is, they are lost if the SNMP agent is rebooted. 4. Due to the large OCTET STRING attributes in this table, the worst case memory requirements for this table are very high. The manager may use the row status attribute of this table to delete rows in order to reclaim memory. 5. The manager may create rows in this table. The SNMP agent may create rows in this table. Only the manager may delete rows in this table. 6. The maximum number of rows allowable in this table is indicated by the scalar attribute adsl2ScalarSCMaxInterfaces. The number of rows available in this table is indicated by the scalar attribute adsl2ScalarSCAvailInterfaces. 7. The SNMP agent is permitted to create rows in this table when a DELT completes successfully or when line initialization occurs. It is not mandatory for the SNMP agent to create rows in this table; hence, it may be necessary for the manager to create rows in this table before any results can be stored. 8. If the manager attempts to create a row in this table and there are no more rows available, the creation attempt will fail, and the response to the SNMP SET PDU will contain the error noCreation(11). 9. If the SNMP agent attempts to create a row in this table and there are no more rows available, the creation attempt will fail, and the attribute adsl2LineCmndConfLdsfFailReason will indicate the reason for the failure. The failure reason will be either tableFull(10) or noResources(11). 10. An example of use of this table is as follows: Step 1. : The DELT is started by setting the : adsl2LineCmndConfLdsf from inhibit to force. Step 2. : The DELT completes, and valid data is : available. Step 3. : The row in the adsl2SCStatusTable where the : results will be stored does not yet exist so : the SNMP agent attempts to create the row. Step 4. : Due to a low memory condition, a row in the : adsl2SCStatusTable table cannot be created at : this time. Step 5. : The reason for the failure, tableFull(10), is : indicated in the adsl2LineCmndConfLdsfFailReason : attribute. 11. Another example of use of this table is as follows : Step 1. : The DELT is started by setting the : adsl2LineCmndConfLdsf from inhibit to force. Step 2. : The DELT completes and valid data is : available. Step 3. : The row in the adsl2SCStatusTable where the : results will be stored does not yet exist so : the SNMP agent attempts to create the row. Step 4. : The row creation is successful. Step 5. : The value of the attribute : adsl2LineCmndConfLdsfFailReasonreason is set : to success(2). 12. Another example of use of this table is as follows: Step 1. : The manager creates a row in adsl2SCStatusTable : for a particular ADSL2 line. Step 2. : The DELT is started on the above-mentioned : line by setting the adsl2LineCmndConfLdsf from : inhibit to force. Step 3. : The DELT completes, and valid data is : available. Step 4. : The value of the attribute : adsl2LineCmndConfLdsfFailReasonreason is set : to success(2). The indexes of this entry are ifIndex and adsl2SCStatusDirection.

The PSD MASK per sub-carrier.An array of 512 16-bits values, designed for supporting up to 512 (downstream) sub-carriers. It ranges from -1400 to -300 units of 0.1 dBm/Hz (physical values are -140 to -30 dBm/Hz). Unit: 0.1 dBm/Hz

SNR Margin is the maximum increase in dB of the noise power received at the ATU (ATU-R on downstream direction and ATU-C on upstream direction), such that the BER requirements are met for all bearer channels received at the ATU. It ranges from -640 to 630 units of 0.1 dB (physical values are -64 to 63 dB). Unit: 0.1 dB

The table hwadsl2PMLineCurrTable contains current Performance Monitoring results of ADSL2 line. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this table are ifIndex and adsl2PMLCurrUnit.

The table hwadsl2PMLineCurrTable contains current Performance Monitoring results of ADSL2 line. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this entry are ifIndex and adsl2PMLCurrUnit.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during current 15 minutes.

This parameter is a count of the INMAME anomalies occurring on the line during current 15 minutes.

This parameter is a count of the INMAIATi anomalies occurring on the line during current 15 minutes.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during current 1 day.

This parameter is a count of the INMAME anomalies occurring on the line during current 1 day.

This parameter is a count of the INMAIATi anomalies occurring on the line during current 1 day.

This parameter is a count of the INMAINPEQi anomalies occurring on the line ever before.

This parameter is a count of the INMAME anomalies occurring on the line ever before.

This parameter is a count of the INMAIATi anomalies occurring on the line ever before.

Count of seconds since agent reset that there was at least one FEC correction event for one or more bearer channels in this line. This parameter is inhibited during UAS or SES. Unit: seconds

Count of seconds since agent reset that there was: ATU-C: CRC-8 >= 1 for one or more bearer channels OR LOS >= 1 OR SEF >= 1 OR LPR >= 1 ATU-R: FEBE >= 1 for one or more bearer channels OR LOS-FE >= 1 OR RDI >= 1 OR LPR-FE >= 1. This parameter is inhibited during UAS. Unit: seconds

Count of seconds since agent reset that there was: ATU-C: (CRC-8 summed over all bearer channels) >= 18 OR LOS >= 1 OR SEF >= 1 OR LPR >= 1 ATU-R: (FEBE summed over all bearer channels) >= 18 OR LOS-FE >= 1 OR RDI >= 1 OR LPR-FE >= 1 This parameter is inhibited during UAS. Unit: seconds

Count of seconds since agent reset that there was LOS (or LOS-FE for ATU-R). Unit: seconds

Count of seconds in Unavailability State since agent reset. Unavailability begins at the onset of 10 contiguous severely -errored seconds, and ends at the onset of 10 contiguous seconds with no severely-errored seconds. Unit: seconds

Start time of the current 15-minute performance statistics.

Start time of the current 1-day performance statistics.

Count of seconds in the current 15 minute interval when there was Loss of Framing. Unit: seconds

Count of seconds in the current 15 minute interval when there was Loss of Link. Unit: seconds

Count of seconds in the current 15 minute interval when there was Loss of Power. Unit: seconds

Count of the number of seconds when there was Loss of Framing during the current day. Unit: seconds

Count of the number of seconds when there was Loss of Link during the current day. Unit: seconds

Count of the number of seconds when there was Loss of Power during the current day. Unit: seconds

Count of the number of seconds when there was Loss of Framing since agent reset. Unit: seconds

Count of the number of seconds when there was Loss of Link since agent reset. Unit: seconds

Count of the number of seconds when there was Loss of Power since agent reset. Unit: seconds

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a near-end leftr defect present observed over the 15 minutes accumulation period.

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the 15 minutes accumulation period.

If retransmission is used in a given transmit direction, this parameter reports the minimum of the EFTR(Error-free throughput rate) observed over the 15 minutes accumulation period.

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a near-end leftr defect present observed over the 24 hours accumulation period.

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the 24 hours accumulation period.

If retransmission is used in a given transmit direction, this parameter reports the minimum of the EFTR(Error-free throughput rate) observed over the 24 hours accumulation period.

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a near-end leftr defect present observed ever before.

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed ever before.

If retransmission is used in a given transmit direction, this parameter reports the minimum of the EFTR(Error-free throughput rate) observed ever before.

The table hwadsl2PMLineHist15MinTable contains Performance Monitoring results of ADSL2 line at last 15 minutes. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this table are ifIndex, adsl2PMLHist15MUnit and adsl2PMLHist15MInterval.

The table hwadsl2PMLineHist15MinTable contains Performance Monitoring results of ADSL2 line at last 15 minutes. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this entry are ifIndex, adsl2PMLHist15MUnit and adsl2PMLHist15MInterval.

This parameter is a count of the INMAINPEQi anomalies occurring on the line at last 15 minutes.

This parameter is a count of the INMAME anomalies occurring on the line at last 15 minutes.

This parameter is a count of the INMAIATi anomalies occurring on the line at last 15 minutes.

Start time of the historical 15-minute performance statistics.

Count of seconds in the interval when there was Loss of Framing. Unit: seconds

Count of seconds in the interval when there was Loss of Link. Unit: seconds

Count of seconds in the interval when there was Loss of Power. Unit: seconds

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a near-end leftr defect present observed over the 15 minutes accumulation period.

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the 15 minutes accumulation period.

If retransmission is used in a given transmit direction, this parameter reports the minimum of the EFTR(Error-free throughput rate) observed over the 15 minutes accumulation period.

The table hwadsl2PMLineHist1DayTable contains Performance Monitoring results of ADSL2 line at last 1 day. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this table are ifIndex, adsl2PMLHist1DUnit and adsl2PMLHist1DInterval.

The table hwadsl2PMLineHist1DayTable contains Performance Monitoring results of ADSL2 line at last 1 day. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this entry are ifIndex, adsl2PMLHist1DUnit and adsl2PMLHist1DInterval.

This parameter is a count of the INMAINPEQi anomalies occurring on the line at last 1 day.

This parameter is a count of the INMAME anomalies occurring on the line at last 1 day.

This parameter is a count of the INMAIATi anomalies occurring on the line at last 1 day.

Start time of the historical 1-day performance statistics.

Count of seconds during this interval that there was Loss of Framing. Unit: seconds

Count of seconds during this interval that there was Loss of Link. Unit: seconds

Count of seconds during this interval that there was Loss of Power. Unit: seconds

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a near-end leftr defect present observed over the 24 hours accumulation period.

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the 24 hours accumulation period.

If retransmission is used in a given transmit direction, this parameter reports the minimum of the EFTR(Error-free throughput rate) observed over the 24 hours accumulation period.

The table hwadsl2PMLineCurrInitTable contains current initialization counters of the ADSL2 line. The PM counters in the table are not reset even when the XTU is reinitialized. They are reinitialized only when the agent itself is reset or reinitialized. The index of this table is ifIndex.

The table hwadsl2PMLineCurrInitTable contains current initialization counters of the ADSL2 line. The PM counters in the table are not reset even when the XTU is reinitialized. They are reinitialized only when the agent itself is reset or reinitialized. The index of this entry is ifIndex.

Count of full initializations attempted on the line (successful and failed) since agent reset.

Count of failed full initializations on the line since agent reset.

Count of short initializations attempted on the line (successful and failed) since agent reset.

Count of failed short initializations on the line since agent reset.

Start time of the current init 15-minute performance statistics.

Start time of the current init 1-day performance statistics.

The table hwadsl2PMLineInitHist15MinTable contains Performance Monitoring results of ADSL2 line initialize at last 15 minutes. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this table are ifIndex and adsl2PMLHistInit15MInterval.

The table hwadsl2PMLineInitHist15MinTable contains Performance Monitoring results of ADSL2 line initialize at last 15 minutes. The PM counters in the table are not reset even when the xtU is reinitialized. They are re-initialized only when the agent itself is reset or reinitialized. The indexes of this entry are ifIndex and adsl2PMLHistInit15MInterval.

Start time of the historical init 15-minute performance statistics.

The table hwadsl2PMLineInitHist1DayTable contains Performance Monitoring results of ADSL2 line initialize at last one day. The indexes of this table are ifIndex and adsl2PMLHistinit1DInterval.

The table hwadsl2PMLineInitHist1DayTable contains Performance Monitoring results of ADSL2 line initialize at last one day. The indexes of this entry are ifIndex and adsl2PMLHistinit1DInterval.

Start time of the historical init 1-day performance statistics.

The table hwadsl2PMChCurrTable contains some extended current Performance Monitoring results of the ADSL2 channel. The PM counters in the table are not reset even when the XTU is reinitialized. They are reinitialized only when the agent itself is reset or reinitialized. The indexes of this table are ifIndex and adsl2PMChCurrUnit.

The table hwadsl2PMChCurrTable contains some extended current Performance Monitoring results of the ADSL2 channel. The PM counters in the table are not reset even when the XTU is reinitialized. They are reinitialized only when the agent itself is reset or reinitialized. The indexes of this entry are ifIndex and adsl2PMChCurrUnit.

Count of units request retransmission on this channel within the current 15 minute interval.

Count of units corrected by retransmission on this channel within the current 15 minute interval.

Count of units uncorrected by retransmission on this channel within the current 15 minute interval.

Count of units request retransmission on this channel during the current day.

Count of units corrected by retransmission on this channel during the current day.

Count of units uncorrected by retransmission on this channel during the current day.

Count of units request retransmission on this channel ever before.

Count of units corrected by retransmission on this channel ever before.

Count of units uncorrected by retransmission on this channel ever before.

Count of CRC-8 (FEBE for ATU-R) anomalies occurring in the channel since agent reset. This parameter is inhibited during UAS or SES. If the CRC is applied over multiple channels, then each related CRC-8 (or FEBE) anomaly should increment each of the counters related to the individual channels.

Count of FEC (FFEC for ATU-R) anomalies (corrected code words) occurring in the channel since agent reset. This parameter is inhibited during UAS or SES. If the FEC is applied over multiple channels, then each related FEC (or FFEC) anomaly should increment each of the counters related to the individual channels.

Start time of the channel current 15-minute performance statistics.

Start time of the channel current 1-day performance statistics.

The table hwadsl2PMChHist15MinTable contains PM channel history for 15min intervals of the ADSL2 channel. The indexes of this table are ifIndex,adsl2PMChHist15MUnit and adsl2PMChHist15MInterval.

The table hwadsl2PMChHist15MinTable contains PM channel history for 15min intervals of the ADSL2 channel. The indexes of this entry are ifIndex,adsl2PMChHist15MUnit and adsl2PMChHist15MInterval.

Count of units request retransmission on this channel within the last 15 minutes interval.

Count of units corrected by retransmission on this channel within the last 15 minutes interval.

Count of units uncorrected by retransmission on this channel within the last 15 minutes interval.

Start time of the historical 15-minute performance statistics.

The table hwadsl2PMChHist1DayTable contains some extended PM channel history for 1-day intervals of ADSL2. The indexes of this table are ifIndex,adsl2PMChHist1DUnit and adsl2PMChHist1DInterval.

The table hwadsl2PMChHist1DayTable contains some extended PM channel history for 1-day intervals of ADSL2. The indexes of this entry are ifIndex,adsl2PMChHist1DUnit and adsl2PMChHist1DInterval.

Count of units request retransmission on this channel within the last 1 day interval.

Count of units corrected by retransmission on this channel within the last 1 day interval.

Count of units uncorrected by retransmission on this channel within the last 1 day interval.

Start time of the historical 1-day performance statistics.

The table hwadsl2LineConfProfTable contains huawei private ADSL2 line profile configuration.Entries in this table MUST be maintained in a persistent manner. The index of this table is adsl2LConfProfProfileName.

The table hwadsl2LineConfProfTable contains huawei private ADSL2 line profile configuration.Entries in this table MUST be maintained in a persistent manner. The index of this entry is adsl2LConfProfProfileName.

The parameter of downstream impulse noise monitoring inter arrival time offset. This is the Inter Arrival Time Offset that the xTU receiver shall use to determine in which bin of the Inter Arrival Time histogram the IAT is reported. The valid values for INMIATO ranges from 3 to 511 DMT symbols in steps of 1 DMT symbol.

The parameter of downstream impulse noise monitoring inter arrival time step. This is the Inter Arrival Time Step that the xTU receiver shall use to determine in which bin of the Inter Arrival Time histogram the IAT is reported. The valid values for INMIATS ranges from 0 to 7 in steps of 1.

The parameter of Downstream impulse noise monitoring cluster continuation value. This is the Cluster Continuation value that the xTU receiver shall use in the cluster indication process described in the relevant ITU-T Recommendation. The valid values for INMCC range from 0 to 64 DMT symbols in steps of 1 DMT symbol.

The parameter of Downstream impulse noise monitoring equivalent impulse noise protect mode. This is the INM Equivalent INP Mode that the xTU receiver shall use in the computation of the Equivalent INP, as defined in the relevant ITU-T Recommendation. The valid values for INM_INPEQ_MODE are 0, 1, 2, 3, and 4.

The RFI notch parameter. It is a string consist of begin tone index, end tone index and psd value. This is a string of 4 groups of values in the following structure: Octets 0+1 - Index of start sub-carrier used in the context of a first group Octets 2+3 - Index of end sub-carrier used in the context of a first group Octet 4+5 - The psd value configurated in the first group Octets 6-11 - Same, for a 2nd group This architecture continues until octets 22-23, which are associated with a 4th group.It can contain as most as 4 groups.

This object configures the clock reference for the ATU-C in an ADSL Line.

This minimum time (in seconds) between an Entry into the L3 state and the L0 or L2 state. Unit: seconds

DPBOESELMIN in dB is the minimum of all main cable losses for the KVz supplied when using the SOL model (expansion of a KVz and ADSL2 provision of additional KVz areas from this KVz using cross-cables to additional KVz), including the KVz at the MSAN site. This value must be adjustable as the minimum requirement via the SNMP interface in the configuration profile for each ADSL2 port, and is set individually for each MSAN site and usage. As an option, adjustment can be done for each MSAN or line card, thus taking effect for entire port groups. It is used only for determining the MUF. Unit: 0.5dB

Enables and disables the trellis mode. This object is defaulted enabled(2).

Enables and disables the bit swap downstream of a line.

Enables and disables the bit swap upstream of a line.

This parameter defines the PSD mask that is assumed to be permitted at the exchange. This parameter shall use the same format as PSDMASKds.The maximum number of breakpoints for DPBOEPSD is 16. This is a string of 16 pairs of values in the following structure: Octets 0+1 - Index of 1st sub-carrier used in the context of a first breakpoint. Octet 2 - The PSD reduction for the sub-carrier indicated in octets 0 and 1 Octets 3-5 - Same, for a 2nd breakpoint Octets 6-8 - Same, for a 3rd breakpoint This architecture continues until octets 45-47, which are associated with a 16th breakpoint. Each subcarrier index is an unsigned number in the range 1 and NSCds. Each PSD reduction value is in the range 0 (0dBm/Hz) to 255 (-127.5dBm/Hz) with steps of 0.5dBm/Hz. Valid values are in the range 0 to 190 (0 to -95dBm/Hz). When the number of breakpoints is less than 16, all remaining octets are set to the value 0xff.

This configuration parameter defines the assumed electrical length of cables (E-side cables) connecting exchange based DSL services to a remote flexibility point (cabinet), that hosts the xTU-C that is subject to spectrally shaped downstream power back-off depending on this length. For this parameter the electrical length is defined as the loss (in dB) of an equivalent length of hypothetical cable at a reference frequency defined by the network operator or in spectrum management regulations. DPBOESEL shall be coded as an unsigned integer representing an electrical length from 0 dB (coded as 0) to 255.5 dB (coded as 511) in steps of 0.5 dB. All values in the range are valid.If DPBOESEL is set to zero, the DPBO in this section shall be disabled. Unit: 0.5dB

This configuration parameter defines a cable model in terms of three scalars DPBOESCMA, DPBOESCMB and DPBOESCMC that shall be used to describe the frequency dependent loss of E-side cables.Parameters DPBOESCMA, DPBOESCMB, DPBOESCMC shall be coded as unsigned integers representing a scalar value from -1 (coded as 0) to 1.5 (coded as 640) in step of 1/256. All values in the range are valid.

This configuration parameter defines a cable model in terms of three scalars DPBOESCMA, DPBOESCMB and DPBOESCMC that shall be used to describe the frequency dependent loss of E-side cables.Parameters DPBOESCMA, DPBOESCMB, DPBOESCMC shall be coded as unsigned integers representing a scalar value from -1 (coded as 0) to 1.5 (coded as 640) in step of 1/256. All values in the range are valid.

This configuration parameter defines a cable model in terms of three scalars DPBOESCMA, DPBOESCMB and DPBOESCMC that shall be used to describe the frequency dependent loss of E-side cables.Parameters DPBOESCMA, DPBOESCMB, DPBOESCMC shall be coded as unsigned integers representing a scalar value from -1 (coded as 0) to 1.5 (coded as 640) in step of 1/256. All values in the range are valid.

DPBOMUS defines the assumed Minimum Usable receive Signal PSD (in dBm/Hz) for exchange based services, used to modify parameter DPBOFMAX defined below. It shall be coded as an unsigned integer representing a PSD level from 0 dBm/Hz (coded as 0) to -127.5 dBm/Hz (coded as 255) in steps of 0.5 dBm/Hz. All values in the range are valid. Unit: 0.5dBm/Hz

DPBOFMIN defines the minimum frequency from which the DPBO shall be applied. It shall be coded as a 16 bits unsigned integer representing a frequency in multiple of 4.3125 KHz. The range of valid values is from 0 kHz (coded as 0) to 8832 kHz (coded as 2048). Unit: 4.3125 KHz

DPBOFMAX defines the maximum frequency at which DPBO may be applied. It shall be coded as a 16 bits unsigned integer representing a frequency in multiple of 4.3125 KHz. The range of valid values is from 138 kHz (coded as 32) to 29997.75 kHz (coded as 6956). Unit: 4.3125 KHz

The table hwadsl2ChConfProfileTable contains huawei private ADSL2 channel profile configuration. Entries in this table MUST be maintained in a persistent manner. The index of this table is adsl2ChConfProfProfileName.

The table hwadsl2ChConfProfileTable contains huawei private ADSL2 channel profile configuration. Entries in this table MUST be maintained in a persistent manner. The index of this entry is adsl2ChConfProfProfileName.

The channel data path mode. Options: 1. atm(1) - ATM data path 2. ptm(2) - PTM data path 3. both(3) - ATM and PTM data path Huawei defined.

Enable or disable the erasure decoding of a channel. Options: 1. enable(1) - Open the erasure decoding of a channel 2. disable(2) - Close the erasure decoding of a channel

To enable or disable the retransmission function of downstream PHY-R. Options: 1. enable(1) - Enable the retransmission function of downstream PHY-R 2. disable(2) - Disable the retransmission function of downstream PHY-R

To enable or disable the retransmission function of upstream PHY-R. Options: 1. enable(1) - Enable the retransmission function of upstream PHY-R 2. disable(2) - Disable the retransmission function of upstream PHY-R

Maximum Impulse Noise Protection on downstream direction.

Maximum Impulse Noise Protection on upstream direction.

This object is used to config the minimum retransmission band width parameter downstream.

This object is used to config the minimum retransmission band width parameter upstream.

This object is used to config the minimum RSoverhead parameter downstream.

This object is used to config the minimum RSoverhead parameter upstream.

The table hwadsl2ChAlarmConfProfileTable contains ADSL2 channel PM thresholds profiles. Entries in this table MUST be maintained in a persistent manner. The index of this table is adsl2ChAlarmConfProfileName.

The table hwadsl2ChAlarmConfProfileTable contains ADSL2 channel PM thresholds profiles. Entries in this table MUST be maintained in a persistent manner. The index of this entry is adsl2ChAlarmConfProfileName.

The channel monitoring rate downstream. When the value you set is larger than the value of the rate downstream defined in the channel profile, it will not be successful. The value 0 means that no threshold is specified for the associated counter. Unit: bits/second

The channel monitoring rate upstream. When the value you set is larger than the value of the rate upstream defined in the channel profile, it will not be successful. The value 0 means that no threshold is specified for the associated counter. Unit: bits/second

The table hwadsl2LineAlarmConfProfileTable contains ADSL2 line PM thresholds profiles. A default profile with an index of 'DEFVAL' will always exist, and its parameters will be set to vendor- specific values, unless otherwise specified in this document. The index of this table is adsl2LineAlarmConfProfileName.

The table hwadsl2LineAlarmConfProfileTable contains ADSL2 line PM thresholds profiles. A default profile with an index of 'DEFVAL' will always exist, and its parameters will be set to vendor- specific values, unless otherwise specified in this document. The index of this entry is adsl2LineAlarmConfProfileName.

A threshold for the hwadsl2PMLCurr15MLeftrs counter, when adsl2PMLCurrUnit is ATUR {2}. The value 0 means that no threshold is specified for the associated counter. Unit: seconds

This object enable/disable the report of LOSS-OF-POWER alarm in an ADSL line. Options: 1. enable(1) - The report of LOSS-OF-POWER alarm in an ADSL line is enabled 2. disable(2) - The report of LOSS-OF-POWER alarm in an ADSL line is disabled Enumeration: 'enable': 1, 'disable': 2.

This object enable/disable the active fail alarm switch. Options: 1. enable(1) - The active fail alarm switch is enabled 2. disable(2) - The active fail alarm switch is disabled Enumeration: 'enable': 1, 'disable': 2.

This object is used to change ADSL management mode. After the mode being changed, system will automatically save data and reboot.

This object is used to change abr-calculation mode. Options: 1. normalMode(1) - Normal abr-calculation mode 2. ptMode(2) - PT abr-calculation mode Enumeration: 'ptMode': 2, 'normalMode': 1.

Indicate the threshold item.

Indicate line template ID.

The reason of activation failure.

The Chipset ID.

Mode switch result. Options: 1. success(0) - Indicates that the adsl mode switch result is success 2. fail(1) - Indicates that the adsl mode switch result is fail Enumeration: 'fail': 1, 'success': 0.

Request ID.

The result of the test. Options: 1. success(0) - Indicates that the test result is success 2. fail(1) - Indicates that the test result is fail Enumeration: 'fail': 1, 'success': 0.

Indicate the threshold value of threshold item.

Indicate the current value of threshold item.

Indicate the threshold value of threshold item.

Indicate the current value of threshold item.

Adsl2 mode switch result trap. This trap message is generated when the result of the recent ADSL mode switch process.

Adsl2 administration mode trap. This trap message is generated when the ADSL mode is the system worked.

NGADSL delt trap. This trap message is generated when delt test result reported.

Adsl2 port status change trap. This trap message is generated when port status changes.

Port automatically trap. This trap message is generated when the ADSL port is automatically deactivated. The ADSL port is automatically deactivated due to the line fault.

Port reactive trap. This trap message is generated when the ADSL port is re-activated after the ADSL line recovers.

Port ATU-R power off trap. This trap message is generated when ATU-R is powered off.

Chipset recover trap. This trap message is generated when the ADSL chipset recovers.

Port deactive trap. This trap message is generated when some xDSL ports or all the xDSL ports are automatically deactivated. Some xDSL ports or all the xDSL ports are automatically deactivated due to lack of licenses.

Line performance statistics trap. This trap message is generated when the line performance statistics of the ADSL port reach the threshold.

ADSL channel downstream activation rate trap. This trap message is generated when the ADSL channel downstream activation rate is lower than the threshold.

Channel performance statistics trap. This trap message is generated when the channel performance statistics of the ADSL port reach the threshold.

ADSL channel upstream activation rate trap. This trap message is generated when the ADSL channel upstream activation rate is lower than the threshold.

ADSL channel upstream rate increases trap. This trap message is generated when the ADSL channel upstream rate increases to a value higher than the threshold.

ADSL channel upstream rate decreases trap. This trap message is generated when the ADSL channel upstream rate decreases to a value lower than the threshold.

ADSL channel downstream rate increases trap. This trap message is generated when the ADSL channel downstream rate increases to a value higher than the threshold.

ADSL channel downstream rate decreases trap. This trap message is generated when the ADSL channel downstream rate decreases to a value lower than the threshold.

Failed active trap. This trap message is generated when it failed to activate the port using the ADSL line configuration parameters.

Chipset not available trap. This trap message is generated when the ADSL chipset is not available.