HUAWEI-ADSL-EXT-MIB: View SNMP OID List / Download MIB

This MIB is used for defining Huawei's ADSL management MIB objects.

This table provides the channel parameters of the ATUR end of each port. The index of this table is ifIndex.

This table provides the channel parameters of the ATUR end of each port. The index of this entry is ifIndex.

Indicates Impulse Noise Protection on upstream direction. The value multiply 1/10000 is the real value. Unit: DMT Symbol

Indicates Reed-Solomon symbols on upstream direction. The value multiply 1/10000 is the real value. Unit: byte

Indicates Reed-Solomon redundancy on upstream direction. Unit: byte

Indicates Reed-Solomon depth on upstream direction. Unit: byte

Indicates the Bit Number of the DMT Symbol on upstream direction. Unit: bit

The bits in the channel that used to retransmission on upstream direction.

Queues in send buffer on upstream direction.

Indicates Reed-Solomon Codeword Size on upstream direction. Range: 0-255 Unit: byte

Indicates Code Gain on upstream direction. It ranges from 0 to 16 units of 0.5 dB (physical values are 0 to 8 dB).

In L2 state, this parameter reports the Net Data Rate in low power state. The data rate is coded in steps of 1000 bit/s.

This object provides the physical layer parameters of each ATUR. The index of this table is ifIndex.

This object provides the physical layer parameters of each ATUR. The index of this entry is ifIndex.

The ATU transmission system capability list of the different coding types. It is coded in a bit-map representation with 1 or more bits set. A bit set to '1' means that the ATU supports the respective coding. The value may be derived from the handshaking procedures defined in G.994.1.

The signal attenuation value on ATUR: It indicates the difference between the transmit signal of the ATU-C and the receive signal of the ATU-R. Range: 0-630 Unit: tenth dB

The ATU G.994.1 Vendor ID as inserted in the G.994.1 CL/CLR message. It consists of 8 binary octets, including a country code followed by a (regionally allocated) provider code, as defined in Recommendation T.35.

The ATU self-test result, coded as a 32-bit value. The most significant octet of the result is '0' if the self-test passed, and '1' if the self-test failed. The interpretation of the other octets is vendor discretionary.

This object provides the channel parameters of each ATUC. The index of this table is ifIndex.

This object provides the channel parameters of each ATUC. The index of this entry is ifIndex.

Indicates Impulse Noise Protection on downstream direction. The value multiply 1/10000 is the real value. If retransmission is used in a given transmit direction, this parameter reports the actual impulse noise protection (INP) against SHINE (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. Unit: DMT Symbol

Indicates Reed-Solomon symbols on downstream direction. The value multiply 1/10000 is the real value. Unit: byte

Indicates Reed-Solomon redundancy on downstream direction. Unit: byte

Indicates Reed-Solomon depth on downstream direction. Unit: byte

Indicates the Bit Number of the DMT Symbol on downstream direction. Unit: bit

The bits in the channel that used to retransmission on downstream direction.

Queues in send buffer on downstream direction.

Indicates Reed-Solomon Codeword Size on downstream direction. Range: 0-255 Unit: byte

Indicates Code Gain on downstream direction. It ranges from 0 to 16 units of 0.5 dB (physical values are 0 to 8 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

Independent whether retransmission is used or not in a given transmit direction: In L0 state, this parameter reports the Net Data Rate (as specified in G.992.3, G.992.5 or G.993.2) at which the bearer channel is operating. In L2 state, the parameter contains the Net Data Rate (as specified in G.992.3, G.992.5 or G.993.2) in the previous L0 state. 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.

In L2 state, this parameter reports the Net Data Rate in low power state. The data rate is coded in steps of 1000 bit/s.

This table contains information on the ADSL line configuration. The index of this table is adslLineConfProfileName.

This table contains information on the ADSL line configuration. The index of this entry is adslLineConfProfileName.

Enables and disables the down bitswap of a template. Options: 1. enabled(1) - Indicates that the downstream bit swap is enabled 2. disabled(2) - Indicates that the downstream bit swap is disabled Default: enabled(1) Enumeration: 'disabled': 2, 'enabled': 1.

Enables and disables the up bitswap of a template. Options: 1. enabled(1) - Indicates that the upstream bit swap is enabled 2. disabled(2) - Indicates that the upstream bit swap is disabled Default: enabled(1) Enumeration: 'disabled': 2, 'enabled': 1.

Enables and disables the Trellions mode. Options: 1. enabled(1) - Indicates that the trellis coding is enabled. 2. disabled(2) - Indicates that the trellis coding is disabled. Default: enabled(1) Enumeration: 'disabled': 2, 'enabled': 1.

Indicates the transmission mode of this channel. Options: 1. all(1) - All (G992.1, G992.2, T1.413)(Default) 2. fullRate(2) - Full rate(G992.1 or T1.413) 3. gliteOnly(3) - G992.2(g.lite) only 4. t1413Only(4) - T1.413 only 5. gdmtOnly(5) - G992.1,G992.3,G992.5,(g.dmt) only 6. ghs(6) - g.hs (G992.1,G992.2,G992.3,G992.4,G992.5,G992.5 is prior) 7. g992Dot1(7) - G992.1 8. g992Dot2(8) - G992.2 9. g992Dot3(9) - G992.3 10. g992Dot4(10) - G992.4 11. g992Dot5(11) - G992.5 12. adslAllOnly(12) - ADSL ALL ONLY 13. adslAndAdsl2(13) - G.992.1,G.992.3,T1.413(Not support) Default: all(1) Enumeration: 'g992Dot2': 8, 'g992Dot3': 9, 'all': 1, 'g992Dot1': 7, 'g992Dot4': 10, 'ghs': 6, 'gliteOnly': 3, 'g992Dot5': 11, 'adslAllOnly': 12, 'adslAndAdsl2': 13, 't1413Only': 4, 'fullRate': 2, 'gdmtOnly': 5.

PVC configuration table of the ADSL port. The indexes of this table are ifIndex,hwAdsllinePvcVpi,and hwAdsllinePvcVci.

PVC configuration table of the ADSL port. The indexes of this entry are ifIndex,hwAdsllinePvcVpi,and hwAdsllinePvcVci.

The VLAN ID of the adsl line PVC. Range: 1-4000

The Priority value of the adsl line PVC. Range: 0-7 Default: 0

The down stream band of the adsl line PVC. Range: 0-450 Default: 0

The up stream band of the adsl line PVC. Range: 0-450

This object allows the adsl line PVC to support multicast. Options: 1. enable(1) - Indicates that the PVC of the ADSL port is enabled to support the multicast 2. disable(2) - Indicates that the PVC of the ADSL port is disabled to support the multicast Default: disable(2) Enumeration: 'enable': 1, 'disable': 2.

This object allows the adsl line PVC to support IGMP. Options: 1. enable(1) - Indicates that the PVC of the ADSL port is enabled to support IGMP 2. disable(2) - Indicates that the PVC of the ADSL port is disabled to support IGMP Default: disable(2) Enumeration: 'enable': 1, 'disable': 2.

The index of the adsl line PVC. Range: 1-8

The Connected type of the adsl line PVC Options: 1. auto(0) - The Connected type of the adsl line PVC is auto 2. llc1483B(1) - The Connected type of the adsl line PVC is llc1483B 3. pppoaLLC(2) - The Connected type of the adsl line PVC is pppoaLLC 4. pppoaVcmux(3) - The Connected type of the adsl line PVC is pppoaVcmux 5. ipoaLLc(4) - The Connected type of the adsl line PVC is ipoaLLc 6. ipoaVcmux(5) - The Connected type of the adsl line PVC is ipoaVcmux Enumeration: 'ipoaLLc': 4, 'auto': 0, 'pppoaLLC': 2, 'ipoaVcmux': 5, 'pppoaVcmux': 3, 'llc1483B': 1.

Row status. Add or delete a table item.

This table includes common attributes describing both ends of the line. The index of this table is ifIndex.

This table includes common attributes describing both ends of the line. The index of this entry is ifIndex.

The value of this object identifies the row in the ADSL Extend Line Configuration Profile Table, (adslLineExtConfProfileTable), which applies to this ADSL line, and channels if applicable. NULL - indicates that there is no extend line profile bound to this port. Range: 0-32

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. Range: 0-32

This hwAdslLineBitAllocationInfoTable contains the detailed bit-allocation information for the current link. This information can be used to determine whether a given sub-carrier loop has sufficient margin to support ADSL data rates, and possibly to determine whether certain specific types of interference or line attenuation exist. The bit allocation information are only valid when the ATU-C is in the C-ACTIVE state. The index of this table is ifIndex.

This hwAdslLineBitAllocationInfoTable contains the detailed bit-allocation information for the current link. This information can be used to determine whether a given sub-carrier loop has sufficient margin to support ADSL data rates, and possibly to determine whether certain specific types of interference or line attenuation exist. The bit allocation information are only valid when the ATU-C is in the C-ACTIVE state. The index of this entry is ifIndex.

Number of bits required per frame in the downstream data path for the current configuration.

Number of bits required per frame in the upstream data path for the current configuration.

when used to Adsl board This object contains the first 128 downstream sub-carrier bit allocations (sub-carrier # 1-128). This object is 64 bytes in length, where each byte contains 2 sub-carrier values. Byte 1 - 64 Downstream bit allocation (first 128 sub-carriers), one byte for two sub-carriers. 1 Bits 4 - 7 # bits in 1st downstream sub-carrier 1 Bits 0 - 3 # bits in 2nd downstream sub-carrier ... 64 Bits 4 - 7 # bits in 127th downstream sub-carrier 64 Bits 0 - 3 # bits in 128th downstream sub-carrier when used to Adsl2+ board This object contains the first 256 downstream sub-carrier bit allocations (sub-carrier # 1-256). This object is 256 bytes in length, where each byte contains 1 sub-carrier values. Byte 1 - 256 Downstream bit allocation (first 256 sub-carriers), one byte for one sub-carriers. 1 Bits 0 - 7 # bits in 1st downstream sub-carrier ... 255 Bits 0 - 7 # bits in 255th downstream sub-carrier 256 Bits 0 - 7 # bits in 256th downstream sub-carrier

when used to Adsl board This object contains the second 128 downstream sub-carrier bit allocations (sub-carrier # 129-256). This object is 64 bytes in length, where each byte contains 2 sub-carrier values. Byte 1 - 64 Downstream bit allocation (second 128 sub-carriers), one byte for two sub-carriers. 1 Bits 4 - 7 # bits in 129th downstream sub-carrier 1 Bits 0 - 3 # bits in 130th downstream sub-carrier ... 64 Bits 4 - 7 # bits in 255th downstream sub-carrier 64 Bits 0 - 3 # bits in 256th downstream sub-carrier when used to Adsl2+ board This object contains the second 256 downstream sub-carrier bit allocations (sub-carrier # 257-512). This object is 256 bytes in length, where each byte contains 1 sub-carrier values. Byte 1 - 256 Downstream bit allocation (second 256 sub-carriers), one byte for one sub-carriers. 1 Bits 0 - 7 # bits in 1st downstream sub-carrier ... 255 Bits 0 - 7 # bits in 255th downstream sub-carrier 256 Bits 0 - 7 # bits in 256th downstream sub-carrier

when used to Adsl board This Object contains 64 upstream sub-carrier bit allocations (sub-carrier # 1-64). This Object is 32 bytes in length, where each byte contains 2 sub-carrier values. Byte 1 - 32 Upstream bit allocation information, total: 32 bytes, one byte for two sub-carriers. 1 Bits 7 - 4 # bits in 1st upstream sub-carrier 1 Bits 3 - 0 # bits in 2nd upstream sub-carrier ... 32 Bits 7 - 4 # bits in 63rd upstream sub-carrier 32 Bits 3 - 0 # bits in 64th upstream sub-carrier when used to Adsl2+ board This Object contains 64 upstream sub-carrier bit allocations (sub-carrier # 1-64). This Object is 64 bytes in length, where each byte contains 1 sub-carrier values. Byte 1 - 64 Upstream bit allocation information, total: 64 bytes, one byte for one sub-carriers. 1 Bits 7 - 0 # bits in 1st upstream sub-carrier ... 64 Bits 7 - 0 # bits in 64th upstream sub-carrier

This table includes xDSL(e.g. adsl,g.shdsl,vdsl...)port information. Used to support common attributes of the ADSL, G.SHDSL, and VDSL ports The index of this table is ifIndex.

This table includes xDSL(e.g. adsl,g.shdsl,vdsl...)port information. Used to support common attributes of the ADSL, G.SHDSL, and VDSL ports The index of this entry is ifIndex.

Set Max MAC count on the xDSL port. Range: 0-255 Default: 255

Set Port monitoring rate threshold percent. Including upstream and downstream. Range: 0-100 Default: 0

Set Port monitoring upstream rate threshold value. Default: 0 Unit:bps

Set Port monitoring downstream rate threshold value. Default: 0 Unit:bps

Enables or disables port rate monitor alarm. Options: 1. enabled(1) - Enables port rate monitor alarm 2. disabled(2) - Disables port rate monitor alarm Enumeration: 'disabled': 2, 'enabled': 1.

Duration of the xDSL port activation Unit: second

NTE power status, this object is defaulted off(2). Options: 1. on(1) - NTE power status is on 2. off(2) - NTE power status is off 3. unknown(3) - NTE power is in unknown status Enumeration: 'on': 1, 'off': 2, 'unknown': 3.

Xdsl port current upstream value. Range: 0-30000 Default: 0

Xdsl port current downstream value. Range: 0-30000 Default: 0

Remote running status of the xDSL port. This object is defaulted unknown(1). Options: 1. unknown(1) - Unknown status 2. noModem(2) - Port is not connected to modem 3. handshake(3) - Handshake status 4. showtime(4) - Port is activated Enumeration: 'showtime': 4, 'unknown': 1, 'noModem': 2, 'handshake': 3.

Xdsl port power state. Options: 1. l0(1) - Full-on state 2. l2(2) - Low power state 3. l3(3) - Idle state 4. l1(4) - Low power state 5. invalidValue(-1) - Invalid state Default: l0(1) Enumeration: 'l2': 2, 'invalidValue': -1, 'l3': 3, 'l0': 1, 'l1': 4.

The up counts of xDSL port.

Admin the up counts of xDSL port. Options: 1. reset(0) - Reset the up counts of xDSL port Enumeration: 'reset': 0.

Last up time of a xDSL port.

Last down time of a xDSL port.

The time when up counts of a xDSL port is cleared.

The retrain counts of xDSL Line.

The last retrain reson of xDSL Line, coded as bit mask. Only one bit can be set valid, all bits set valid means invalid retrain reason.

Loop flag. Options: 1. false(0) - No loop 2. true (1) - Loop Enumeration: 'false': 0, 'true': 1.

Set Port monitoring upstream rate threshold percent value. Range: 0-100 Default: 0

Set Port monitoring downstream rate threshold percent value. Range: 0-100 Default: 0

This table provides one row for each ADSL PORT. Each row contains the preactived parameters. The index of this table is ifIndex.

This table provides one row for each ADSL PORT. Each row contains the preactived parameters. The index of this entry is ifIndex.

Noise Margin as seen by this ATU-C at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB

Noise Margin as seen by this ATU-R at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB

Indicates the maximum attainable data rate by the ATU-C at the time of the last adslAtucRateChangeTrap event. Unit: bps

Indicates the maximum attainable data rate by the ATU-R at the time of the last adslAtucRateChangeTrap event. Unit: bps

Measured difference in the total power transmitted as seen by this ATU-C at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB

Measured difference in the total power transmitted as seen by this ATU-R at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB

The last time at that the port was activated.

Adsl port three priority table. The index of this table is ifIndex.

Adsl port three priority table. The index of this entry is ifIndex.

Three Priority status of the interface. Options: 1. enable(1) - Adsl port three priority is enabled 2. disable(2) - Adsl port three priority is disabled Enumeration: 'enable': 1, 'disable': 2.

Max mac learning no limit table. The indexes of this table are hwFrameIndex and hwSlotIndex.

Max mac learning no limit table. The indexes of this entry are hwFrameIndex and hwSlotIndex.

This object is used to set whether all the ports in the slot limits the maximum number of learning MAC addresses. Options: 1. enable(1) - Don't limit the max NO. of learning mac addresses in the slot 2. disable(2) - Limit the max NO. of learning mac addresses in the slot Enumeration: 'enable': 1, 'disable': 2.

XDSL port state staticstic table. Used to support the statistics information about the status mapping and status of ports on service boards, such as the ADSL, G.SHDSL, and VDSL boards The indexes of this table are ifType, hwFrameIndex, hwSlotIndex.

XDSL port state staticstic table. Used to support the statistics information about the status mapping and status of ports on service boards, such as the ADSL, G.SHDSL, and VDSL boards The indexes of this entry are ifType, hwFrameIndex, hwSlotIndex.

This object is port number of one slot.

The type of port status: 2 failed; 8 testing; 9 activated; 10 activating; 11 deactivated; 18 localloopback; 19 remoteloopback; 20 blocked; 37 utopialoopback; 38 afeloopback; 39 hybridloopback; 255 unknown; The hwXdslPortStateBitmapListInfo describes the states of all ports. Every byte describe the current state of every port. The length is equal to the value of the hwXdslPortStatePortNumberInfo.

The total of the activated ports.

The total of the deactivated ports.

The total of the activating ports.

The total of the Testing ports.

The total of the blocked ports.

The total of the local testing ports.

The total of the remote testing ports.

The total of the failed ports.

The total of the unknown xDSL ports.

This table contains information on the ADSL extend line configuration. One entry in this table reflects a extend line profile defined by a manager which can be used to configure the ADSL line. The index of this table is hwadslLineExtConfProfileNameCfg.

This table contains information on the ADSL extend line configuration. One entry in this table reflects a extend line profile defined by a manager which can be used to configure the ADSL line. The index of this entry is hwadslLineExtConfProfileNameCfg.

This object is used by the hwadslLineExtConfProfileTable in order to identify a row of this table. Indicates the name of the extended line profile.

The begin index of the first section. Range: 0-511

The end index of the first section. Range: 0-511

The enable flag of the first section. Options: 1. enabled(1) - The first tone section is enabled 2. disabled(2) - The first tone section is disabled Enumeration: 'disabled': 2, 'enabled': 1.

The begin index of the second section. Range: 0-511

The end index of the second section. Range: 0-511

The enable flag of the second section. Options: 1. enabled(1) - The second tone section is enabled 2. disabled(2) - The second tone section is disabled Enumeration: 'disabled': 2, 'enabled': 1.

The begin index of the third section. Range: 0-511

The end index of the third section. Range: 0-511

The enable flag of the third section. Options: 1. enabled(1) - The third tone section is enabled 2. disabled(2) - The third tone section is disabled Enumeration: 'disabled': 2, 'enabled': 1.

The begin index of the fourth section. Range: 0-511

The end index of the fourth section. Range: 0-511

The enable flag of the fourth section. Options: 1. enabled(1) - The fourth tone section is enabled 2. disabled(2) - The fourth tone section is disabled Enumeration: 'disabled': 2, 'enabled': 1.

If retransmission is not used in downstream direction,this parameter is minimum impulse noise protection on downstream direction. The minimum impulse noise protection for the bearer channel, expressed in symbols. The parameter can take the following values: noProtection(0), halfSymbol(1), singleSymbol(2), twoSymbols(4), threeSymbols(6), fourSymbols(8), fiveSymbols(10), sixSymbols(12), sevenSymbols(14), eightSymbols(16), nineSymbols(18), tenSymbols(20), elevenSymbols(22), twelveSymbols(24), thirteenSymbols(26), fourteenSymbols(28), fifteenSymbols(30), sixteenSymbols(32), null(65535) The value multiply 1/2 is the real value of Noise Protection values.

If retransmission is not used in upstream direction,this parameter is minimum impulse noise protection on upstream direction. The minimum impulse noise protection for the bearer channel, expressed in symbols. The parameter can take the following values: noProtection(0), halfSymbol(1), singleSymbol(2), twoSymbols(4), threeSymbols(6), fourSymbols(8), fiveSymbols(10), sixSymbols(12), sevenSymbols(14), eightSymbols(16), nineSymbols(18), tenSymbols(20), elevenSymbols(22), twelveSymbols(24), thirteenSymbols(26), fourteenSymbols(28), fifteenSymbols(30), sixteenSymbols(32), null(65535) The value multiply 1/2 is the real value of Noise Protection values.

Maximum Trainning Margin in downstream. Range: 0-310 Default: 30 Unit: tenth dB

Maximum Trainning Margin in upstream. Range: 0-310 Default: 30 Unit: tenth dB

Maximum PSD margin in downstream.

The downstream PSD mask applicable at the U-C2 reference point. This parameter is used only for G992.3 or G992.5 and it may impose PSD restrictions (breakpoints) in addition to the Limit PSD mask defined in G992.5. This is a string of 32 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 94-95, which are associated with a 32nd 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 32, all remaining octets are set to the value 0. Note that the content of this object should be correlated with the sub-carriers mask and with the RFI setup.

The transmission stardard mask . The Mask bit and the corresponding Transmission Standard: 0x 1 1 1 1 1 1 ETSI T1.413 G992.5 G992.3 G992.2 G992.1 The Default BitMask: 0X0.

The transMission annex Mask. The Mask bit and the corresponding Transmission Annex: 0x 1 1 1 1 1 Annex .J Annex .M Annex .L Annex .B Annex .A The Default BitMask: 0X0.

Annex M expand scope: 1-Tone Index(7~32) 2-Tone Index(7~36) 3-Tone Index(7~40) 4-Tone Index(7~44) 5-Tone Index(7~48) 6-Tone Index(7~52) 7-Tone Index(7~56) 8-Tone Index(7~60) 9-Tone Index(7~64) -1-invalidValue

The state of L2 power management mode. Options: 1. disabled(1) - The L2 power management mode is disabled 2. enabled(2) - The L2 power management mode is enabled 3. forced(3) - The L2 power management mode is forced Default: disabled(1) Enumeration: 'disabled': 1, 'forced': 3, 'enabled': 2.

Minimum data rate in L2 mode. Range: 128-16384 Default: 256 Unit: Kbps

Maximum data rate in L2 mode. Range: 128-16384 Default: 1024 Unit: Kbps

Threshold for the Payload Rate Ratio. Range: 128-16384 Default: 128 Unit: Kbps

Guard time before entering L2 mode. Range: 0-1024 Default: 60 Unit: seconds

The minimum interval between two records of L2 mode. Range: 0-255 Default: 255 Unit: seconds

Maximum aggregate transmit power reduction per L2 request or L2 power trim. Range: 0-31 Default: 3 Unit: db

Total maximum aggregate transmit power reduction in L2. Range: 0-31 Default: 9 Unit: db

To enable or disable the PHY-R function on upstream direction. Options: 1. enable(1) - The PHY-R function on upstream direction is enabled 2. disable(2) - The PHY-R function on upstream direction is disabled Default: disable(2) Enumeration: 'enable': 1, 'disable': 2.

Maximum Impulse Noise Protection on upstream direction. The parameter can take the following values: noProtection(1), halfSymbol(2), singleSymbol(3), twoSymbols(4), threeSymbols(5), fourSymbols(6), fiveSymbols(7), sixSymbols(8), sevenSymbols(9), eightSymbols(10), nineSymbols(11), tenSymbols(12), elevenSymbols(13), twelveSymbols(14), thirteenSymbols(15), fourteenSymbols(16), fifteenSymbols(17), sixteenSymbols(18) The value multiply 1/2 is the real value of Noise Protection values. Default: 1 Unit: DMT Symbol

Minimum rtx ratio on upstream direction. Range: 0-255 Default: 0 Unit: 1/256

The minimum value of R/N on upstream direction. Range: 0-128 Default: 0 Unit: 1/256

To enable or disable the PHY-R function on downstream direction. Options: 1. enable(1) - The PHY-R function on downstream direction is enabled 2. disable(2) - The PHY-R function on downstream direction is disabled Default: disable(2) Enumeration: 'enable': 1, 'disable': 2.

Maximum Impulse Noise Protection on downstream direction. The parameter can take the following values: noProtection(1), halfSymbol(2), singleSymbol(3), twoSymbols(4), threeSymbols(5), fourSymbols(6), fiveSymbols(7), sixSymbols(8), sevenSymbols(9), eightSymbols(10), nineSymbols(11), tenSymbols(12), elevenSymbols(13), twelveSymbols(14), thirteenSymbols(15), fourteenSymbols(16), fifteenSymbols(17), sixteenSymbols(18) The value multiply 1/2 is the real value of Noise Protection values. Default: 1 Unit: DMT Symbol

Minimum rtx ratio on downstream direction. Range: 0-255 Default: 0 Unit: 1/256

The minimum value of R/N on downstream direction. Range: 0-128 Default: 0 Unit: 1/256

The upstream PSD mask applicable at the U-C2 reference point. This parameter is used only for G992.3 or G992.5 and it may impose PSD restrictions (breakpoints) in addition to the Limit PSD mask defined in G992.5. This is a string of 32 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 9-11, which are associated with a fourth breakpoint. Each subcarrier index is an unsigned number in the range 1 and NSCus. 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 4, all remaining octets are set to the value 0. Note that the content of this object should be correlated with the sub-carriers mask and with the RFI setup.

The ADSL2 management model specified includes an ADSL Mode attribute which identifies an instance of ADSL Mode-Specific PSD Configuration object in the ADSL Line Profile. The following classes of ADSL operating mode are defined. Options: 1. defMode(1) - ADSL transmit mode is defMode 2. adsl(2) - ADSL transmit mode is adsl 3. adsl2Pots(3) - ADSL transmit mode is adsl2Pots 4. adsl2Isdn(4) - ADSL transmit mode is adsl2Isdn 5. adsl2PlusPots(5) - ADSL transmit mode is adsl2PlusPots 6. adsl2PlusIsdn(6) - ADSL transmit mode is adsl2PlusIsdn 7. adsl2ReachExtended(7) - ADSL transmit mode is adsl2ReachExtended 8. invalidValue(-1) - Invalid value Enumeration: 'invalidValue': -1, 'adsl2Pots': 3, 'adsl2Isdn': 4, 'adsl2ReachExtended': 7, 'adsl2PlusPots': 5, 'adsl2PlusIsdn': 6, 'defMode': 1, 'adsl': 2.

This object is used to create a new row or modify or delete an existing row in this table. A profile activated by setting this object to 'active'. When 'active' is set, the system will validate the profile. Before a profile can be deleted or taken out of service, (by setting this object to 'destroy' or 'outOfService') it must be first unreferenced from all associated lines. If the implementator of this MIB has chosen not to implement 'dynamic assignment' of profiles, this object's MIN-ACCESS is read-only and its value is always to be 'active'.

This minimum time (in seconds) between an entry into the L2 state and the first power trim in the L2 state and between two consecutive power trims in the L2 State. It ranges from 0 to 255 seconds. Range: 0-255 Default: 30 Unit: seconds

The mode of operation of G.998.4 retransmission in downstream direction. Options: 1. forbidden(0) - G.998.4 retransmission not allowed. 2. preferred(1) - G.998.4 retransmission is preferred. 3. forced(2) - Force the use of the G.998.4 retransmission. 4. testmode(3) - Force the use of the G.998.4 retransmission in test mode. Enumeration: 'forced': 2, 'forbidden': 0, 'testmode': 3, 'preferred': 1.

If retransmission is used in downstream direction, this parameter specifies the threshold for declaring a near-end leftr defect. The value is coded as a fraction of the NDR with valid range from 0.01 to 0.99 with increments of 0.01. A special value means the ETR shall be used as the default threshold for declaring a leftr defect.

If retransmission is used in downstream direction, this parameter specifies the minimum expected throughput for the bearer channel.The values range in steps of 1000 bit/s.

If retransmission is used in downstream direction, this parameter specifies the maxmum expected throughput for the bearer channel.The values range in steps of 1000 bit/s.

If retransmission is used in downstream direction, this parameter specifies the maximum net data rate for the bearer channel. The values range in steps of 1000 bit/s.

If retransmission is used in downstream direction, this parameter specifies the maximum for the instantaneous delay due to the effect of retransmission only (see G.998.4 for detailed specification). The delay ranges from 1 to 63 ms by steps of 1 ms. Unit: milliseconds

If retransmission is used in downstream direction, this parameter specifies the minimum for the instantaneous delay due to the effect of retransmission only (see G.998.4 for detailed specification). The delay ranges from 0 to 63 ms by steps of 1 ms. Unit: milliseconds

If retransmission is used in downstream direction, this parameter specifies the minimum impulse noise protection against SHINE for the bearer channel if it is transported over DMT symbols with a subcarrier spacing of 4.3125 kHz. The impulse noise protection is expressed in DMT symbols with a subcarrier spacing of 4.3125 kHz and can take any integer value from 0 to 63, inclusive. Unit: symbols

If retransmission is used in downstream direction, this parameter specifies the SHINE ratio (detailed definition see G.998.4). The values range from 0 to 0.100 in increments of 0.001.

If retransmission is used in downstream direction, this parameter specifies the minimum impulse noise protection against REIN for the bearer channel if it is transported over DMT symbols with a subcarrier spacing of 4.3125 kHz. The impulse noise protection is expressed in DMT symbols with a subcarrier spacing of 4.3125 kHz and can take any integer value from 0 to 7, inclusive.

If retransmission is used in downstream direction, this parameter specifies the inter-arrival time that shall be assumed for REIN protection. Options: 1. frequency100Hz(0) - an inter-arrival time derived from a REIN at 100 Hz 2. frequency120Hz(1) - an inter-arrival time derived from a REIN at 120 Hz Enumeration: 'frequency120Hz': 1, 'frequency100Hz': 0.

This object configures the clock reference for the ATU-C in an ADSL line. Represented as an enumeration. Options: 1. freeRun(1) - Indicates the local clock 2. system(2) - Indicates the system clock Enumeration: 'freeRun': 1, 'system': 2.

The RFI notch parameter. It is a string consist of begin tone index, end tone index. 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 Octets 4-7 - Same, for a 2nd group This architecture continues until octets 12-15, which are associated with a 4th group.It can contain as most as 4 groups.

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.

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.

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.

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 2203.6875 kHz (coded as 511).

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 2203.6875 kHz (coded as 511).

Maximum PSD margin in upstream.

The maximum nominal aggregate transmit power in the downstream direction during initialization and showtime. It ranges from 0 to 255 units of 0.1 dBm (physical values are 0 to 25.5 dBm).

The maximum nominal aggregate transmit power in the upstream direction during initialization and showtime. It ranges from 0 to 255 units of 0.1 dBm (physical values are 0 to 25.5 dBm).

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 parameter indicates that the framer settings of the upstream bearer shall be selected such that the impulse noise protection computed according to the formula specified in the relevant recommendation is greater than or equal to the minimal impulse noise protection requirement. This flag shall have the same value for all the bearers of one line in the same direction.

The parameter indicates that the framer settings of the upstream bearer shall be selected such that the impulse noise protection computed according to the formula specified in the relevant recommendation is greater than or equal to the minimal impulse noise protection requirement. This flag shall have the same value for all the bearers of one line in the same direction.

If retransmission is not used in a given transmit direction, this parameter indicates which policy shall be applied to determine the transceiver configuration parameters at initialization. The valid values for CIPOLICY are 0,1 and 2. Those policies are defined in the respective recommendations. Options: 1. policy0 (1) - Policy 0 according to the applicable standard 2. policy1 (2) - Policy 1 according to the applicable standard 3. policy2 (3) - Policy 2 according to the applicable standard Enumeration: 'policy1': 2, 'policy0': 1, 'policy2': 3.

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

Power management state enabling. The state of L3 power management mode. Options: 1. enabled(1) - The L3 power management mode is enabled 2. disabled(2) - The L3 power management mode is disabled Enumeration: 'disabled': 2, 'enabled': 1.

This table provides one row for each ADSL port. Each row contains the latest actived parameters. The index of this table is ifIndex.

This table provides one row for each ADSL port. Each row contains the latest actived parameters. The index of this entry is ifIndex.

Actual time when latest actived.

Actual time when latest deactived. If port is actived, the value is invalid.

Actual transmit rate on this channel when latest actived. Unit: bps

Actual transmit rate on this channel when latest actived. Unit: bps

Noise Margin as seen by this ATU-C at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB.

Noise Margin as seen by this ATU-R at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB.

Measured difference in the total power transmitted as seen by this ATU-C at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB.

Measured difference in the total power transmitted as seen by this ATU-R at the time of the last adslAtucRateChangeTrap event. Unit: tenth dB.

Indicates the maximum attainable data rate by the ATU-C at the time of the last adslAtucRateChangeTrap event. Unit: bps

Indicates the maximum attainable data rate by the ATU-R at the time of the last adslAtucRateChangeTrap event. Unit: bps

Configured transmit rate for ADSL port. See adslAtucConfRateChanRatio for information regarding RADSL mode and ATUR transmit rate for ATUC receive rates. Unit: bps.

Configured receive rate for ADSL port. See adslAtucConfRateChanRatio for information regarding RADSL mode and ATUR transmit rate for ATUC receive rates. Unit: bps.

Interleave delay for this channel when latest actived. Unit: milliseconds

Interleave delay for this channel when latest actived. Unit: milliseconds

Port Signal/Noise Margin. Range: 0-310 Unit: tenth dB

Port Signal/Noise Margin. Range: 0-310 Unit: tenth dB

Port down stream threshold. Unit: bps

Port up stream threshold. Unit: bps

XDSL port performance staticstic table. The indexes of this table are ifIndex and hwXdslPort15minutesPerformanceIntervalInfo.

XDSL port performance staticstic table. The indexes of this entry are ifIndex and hwXdslPort15minutesPerformanceIntervalInfo.

The index of the interval which is queried. Range: 0-96

Read the receive bytes of xDSL port during 15 minutes.

Read the transmit bytes of xDSL port during 15 minutes.

Number of successful activations of the ADSL/G.SHDSL port within 15 minutes

Number of failed activations of the ADSL/G.SHDSL port within 15 minutes

Number of head errors of the ATUC cell within 15 minutes.

Number of head errors of the ATUR cell within 15 minutes.

Seconds of the ATUC FEC errors within 15 minutes.

Seconds of the ATUR FEC errors within 15 minutes.

Read the Stat. time of current 15 minutes.

This table provides the physical layer parameters of each ATUC. The index of this table is ifIndex.

This table provides the physical layer parameters of each ATUC. The index of this entry is ifIndex.

A set of ADSL line transmission modes.

Current signal attenuation of the ATU-C, indicating the difference between the transmit signal of the ATU-R and the receive signal of the ATU-C. Range: 0-630 Unit: tenth dB

The ATU G.994.1 Vendor ID as inserted in the G.994.1 CL/CLR message. It consists of 8 binary octets, including a country code followed by a (regionally allocated) provider code, as defined in Recommendation T.35.

The ATU self-test result, coded as a 32-bit value. The most significant octet of the result is '0' if the self-test passed, and '1' if the self-test failed. The interpretation of the other octets is vendor discretionary.

The ATU transmission system capability list of the different coding types. It is coded in a bit-map representation with 1 or more bits set. A bit set to '1' means that the ATU supports the respective coding. The value may be derived from the handshaking procedures defined in G.994.1.

This table is an extension of RFC 2662. It contains ADSL line configuration and monitoring information. This includes the ADSL line's capabilities and actual ADSL transmission system. An entry extends the adslLineEntry defined in [RFC2662]. Each entry corresponds to an ADSL line. The index of this table is ifIndex.

This table is an extension of RFC 2662. It contains ADSL line configuration and monitoring information. This includes the ADSL line's capabilities and actual ADSL transmission system. An entry extends the adslLineEntry defined in [RFC2662]. Each entry corresponds to an ADSL line. The index of this entry is ifIndex.

The actual transmission mode of the ATU-C. During ADSL line initialization, the ADSL Transceiver Unit - Remote terminal end (ATU-R) will determine the mode used for the link. This value will be limited a single transmission mode that is a subset of those modes enabled by the ATU-C and denoted by adslLineTransAtucConfig. After an initialization has occurred, its mode is saved as the 'Current' mode and is persistence should the link go down. This object returns 0 (i.e. BITS with no mode bit set) if the mode is not known.

This parameter specifies whether G.998.4 retransmission is used (i.e., active in Showtime) in a given transmit direction. The parameter in downstream is RTX_USED_ds, and the parameter in upstream is RTX_USED_us. In G.992.3 and G992.5 only the downstream parameter RTX_USED_ds is relevant, the value in the upstream direction shall be ignored. In G.993.2, both parameters are relevant. 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 This parameter shall also be reported in the case of RTX_MODE=RTX_FORCED with INIT FAILURE or with RTX_MODE=RTX_TESTMODE with INIT FAILURE. Enumeration: 'rtxUnusedNotSupportedXtur': 4, 'rtxInuse': 1, 'rtxUnusedNotSupportedXtucAndXtur': 5, 'rtxUnusedNotSupportedXtuc': 3, 'invalidValue': -1, 'rtxUnusedModeForbidden': 2.

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 Enumeration: 'invalidValue': -1, 'configNotFeasible': 2, 'ginpNotSelected': 6, 'otherCause': 5, 'configError': 1, 'commFail': 3, 'noPeerXt': 4, 'noFail': 0.

The measured difference in the total power transmitted by the ATU-C and the total power received by the ATU-R over all sub- carriers during Showtime. It ranges from 0 to 1270 units of 0.1 dB (physical values are 0 to 127 dB). A special value of 0x7FFFFFFF (2147483647) indicates the signal attenuation is out of range to be represented. A special value of 0x7FFFFFFE (2147483646) indicates the signal attenuation measurement is currently unavailable.

The measured difference in the total power transmitted by the ATU-R and the total power received by the ATU-C over all sub- carriers during Showtime. It ranges from 0 to 1270 units of 0.1 dB (physical values are 0 to 127 dB). A special value of 0x7FFFFFFF (2147483647) indicates the signal attenuation is out of range to be represented. A special value of 0x7FFFFFFE (2147483646) indicates the signal attenuation measurement is currently unavailable.

Actual Power Spectrum Density (PSD) Downstream. The average downstream transmit PSD over the sub-carriers used for downstream. It ranges from -900 to 0 units of 0.1 dB (physical values are -90 to 0 dBm/Hz). A value of 0x7FFFFFFF (2147483647) indicates the measurement is out of range to be represented.

Actual Power Spectrum Density (PSD) Upstream. The average upstream transmit PSD over the sub-carriers used for upstream. It ranges from -900 to 0 units of 0.1 dB (physical values are -90 to 0 dBm/Hz). A value of 0x7FFFFFFF (2147483647) indicates the measurement is out of range to be represented.

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

Parameter table of the ATUC channel performance: This table is used to query the performance statistics of the ATUC channel. The index of this table is ifIndex.

Parameter table of the ATUC channel performance: This table is used to query the performance statistics of the ATUC channel. The index of this entry is ifIndex.

The count of all blocks received with FEC anomalies since agent reset.

The count of all blocks received with HEC anomalies since agent reset.

The count of all blocks received with CRC anomalies since agent reset.

The count of all blocks received with FEC anomalies on this channel within the current 15 minutes interval.

The count of all blocks received with HEC anomalies on this channel within the current 15 minutes interval.

The count of all blocks received with CRC anomalies on this channel within the current 15 minutes interval.

The count of all blocks received with FEC anomalies on this channel during the current day as measured by adslAtucChanPerfCurr1DayTimeElapsed.

The count of all blocks received with HEC anomalies on this channel during the current day as measured by adslAtucChanPerfCurr1DayTimeElapsed.

The count of all blocks received with CRC anomalies on this channel during the current day as measured by adslAtucChanPerfCurr1DayTimeElapsed.

The count of all blocks received with FEC anomalies on this channel within the most recent previous 1-day period.

The count of all blocks received with HEC anomalies on this channel within the most recent previous 1-day period.

The count of all blocks received with CRC anomalies on this channel within the most recent previous 1-day period.

The count of units request retransmission since agent reset.

The count of units corrected by retransmission since agent reset.

The count of units uncorrected by retransmission since agent reset.

The count of units request retransmission on this channel within the current 15 minutes interval.

The count of units corrected by retransmission on this channel within the current 15 minutes interval.

The count of units uncorrected by retransmission on this channel within the current 15 minutes interval.

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

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

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

The count of units request retransmission on this channel within the most recent previous 1-day period.

The count of units corrected by retransmission on this channel within the most recent previous 1-day period.

The count of units uncorrected by retransmission on this channel within the most recent previous 1-day period.

Start time of the current 15-minute performance statistics.

Start time of the current 1-day performance statistics.

Parameter table of the ATUR channel performance: This table is used to query the performance statistics of the ATUR channel. The index of this table is ifIndex.

Parameter table of the ATUR channel performance: This table is used to query the performance statistics of the ATUR channel. The index of this entry is ifIndex.

The count of all blocks received with FEC anomalies since agent reset.

The count of all blocks received with HEC anomalies since agent reset.

The count of all blocks received with CRC anomalies since agent reset.

The count of all blocks received with FEC anomalies on this channel within the current 15 minutes interval.

The count of all blocks received with HEC anomalies on this channel within the current 15 minutes interval.

The count of all blocks received with CRC anomalies on this channel within the current 15 minutes interval.

The count of all blocks received with FEC anomalies on this channel during the current day as measured by adslAturChanPerfCurr1DayTimeElapsed.

The count of all blocks received with HEC anomalies on this channel during the current day as measured by adslAturChanPerfCurr1DayTimeElapsed.

The count of all blocks received with CRC anomalies on this channel during the current day as measured by adslAturChanPerfCurr1DayTimeElapsed.

The count of all blocks received with FEC anomalies on this channel within the most recent previous 1-day period.

The count of all blocks received with HEC anomalies on this channel within the most recent previous 1-day period.

The count of all blocks received with HEC anomalies on this channel within the most recent previous 1-day period.

The count of units request retransmission since agent reset.

The count of units corrected by retransmission since agent reset.

The count of units uncorrected by retransmission since agent reset.

The count of units request retransmission on this channel within the current 15 minutes interval.

The count of units corrected by retransmission on this channel within the current 15 minutes interval.

The count of units uncorrected by retransmission on this channel within the current 15 minutes interval.

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

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

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

The count of units request retransmission on this channel within the most recent previous 1-day period.

The count of units corrected by retransmission on this channel within the most recent previous 1-day period.

The count of units uncorrected by retransmission on this channel within the most recent previous 1-day period.

Start time of the current 15-minute performance statistics.

Start time of the current 1-day performance statistics.

Period table of collecting the ATUR channel performance data. This table is used to query the ATUR channel performance data collected in each period (a day is divided into 96 15-minute periods). The indexes of this table are ifIndex and adslAturChanIntervalNumber.

Period table of collecting the ATUR channel performance data. This table is used to query the ATUR channel performance data collected in each period (a day is divided into 96 15-minute periods). The indexes of this entry are ifIndex and adslAturChanIntervalNumber.

The count of all blocks received with FRC anomalies on this channel during this interval.

The count of all blocks received with HRC anomalies on this channel during this interval.

The count of all blocks received with CRC anomalies on this channel during this interval.

The count of units request retransmission on this channel during this interval.

The count of units corrected by retransmission on this channel during this interval.

The count of units uncorrected by retransmission on this channel during this interval.

Start time of the historical 15-minute performance statistics.

This table contains information on the ADSL line configuration. One entry in this table reflects a profile defined by a manager which can be used to configure the modem for a physical line. The entry contains information on the ADSL line configuration. Each entry consists of a list of parameters that represents the configuration of an ADSL modem. When 'dynamic' profiles are implemented, a default profile will always exist. This profile's name will be set to 'DEFVAL' and its parameters will be set to vendor specific values, unless otherwise specified in this document. When 'static' profiles are implemented, profiles are automatically created or destroyed as ADSL physical lines are discovered and removed by the system. The name of the profile will be equivalent to the decimal value of the line's interface index. The index of this table is adslLineAlarmConfProfileName.

This table contains information on the ADSL line configuration. One entry in this table reflects a profile defined by a manager which can be used to configure the modem for a physical line. The entry contains information on the ADSL line configuration. Each entry consists of a list of parameters that represents the configuration of an ADSL modem. When 'dynamic' profiles are implemented, a default profile will always exist. This profile's name will be set to 'DEFVAL' and its parameters will be set to vendor specific values, unless otherwise specified in this document. When 'static' profiles are implemented, profiles are automatically created or destroyed as ADSL physical lines are discovered and removed by the system. The name of the profile will be equivalent to the decimal value of the line's interface index. The index of this entry is adslLineAlarmConfProfileName.

This object enables/disables the report of LOSS-OF-POWER alarm in an ADSL line. This object is defaulted enable(1). 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 Default: enable(1) Enumeration: 'enable': 1, 'disable': 2.

A threshold for the hwAdslAturPerfCurr15MLeftrs counter, The value 0 means that no threshold is specified for the associated counter. Unit: seconds

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 table is used to describe the performance statistics of the ADSL port within 15 minutes. The indexes of this table are ifIndex and hwAdslPort15minutesPerformanceIntervalIndex.

This table is used to describe the performance statistics of the ADSL port within 15 minutes. The indexes of this entry are ifIndex and hwAdslPort15minutesPerformanceIntervalIndex.

The index of the interval which is queried. Range: 0-96

Read the received bytes of xDSL port during 15 minutes.

Read the transmitted bytes of xDSL port during 15 minutes.

Number of successful activations within 15 minutes.

Number of failed activations within 15 minutes.

Seconds of head errors of the ATUC cell within 15 minutes.

Seconds of the head errors of the ATUC cell within 15 minutes.

Seconds of the ATUC FEC errors within 15 minutes.

Seconds of the ATUR FEC errors within 15 minutes.

Seconds that is passed within the current 15 minutes.

ATUC cells discarded with HEC Errors.

ATUR cells discarded with HEC Errors.

The value of this object identifies the row in the ADSL Line Configuration Profile Table, (adslLineConfProfileTable), which applies for this ADSL line, and channels if applicable. For 'dynamic' mode, in the case which the configuration profile has not been set, the value will be set to 'DEFVAL'. If the implementator of this MIB has chosen not to implement 'dynamic assignment' of profiles, this object's MIN-ACCESS is read-only.

The up time in the interval. Unit: seconds

Measured difference in the total power transmitted by the peer ATU and the total power received by this ATU. Range: 0-630 Unit: tenth dB

Noise Margin as seen by this ATU with respect to its received signal. Unit: tenth dB

Indicates the maximum currently attainable data rate by the ATU. This value will be equal or greater than the current line rate. Unit: bps

The actual transmitted rate on this channel. Unit: bps

Measured difference in the total power transmitted by the peer ATU and the total power received by this ATU. Range: 0-630 Unit: tenth dB

Noise Margin as seen by this ATU with respect to its received signal. Range: (-640)-(640) Unit: tenth dB

Indicates the maximum currently attainable data rate by the ATU. This value will be equal or greater than the current line rate. Unit: bps

The actual transmitted rate on this channel. Unit: bps

Seconds of the ATU-C errors at the interval. Unit: seconds

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

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

The count of seconds in the interval when there was Loss of Signal. Unit: seconds

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

Seconds of the ATU-R errors at the interval. Unit: seconds

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

The count of seconds in the interval when there was Loss of Signal. Unit: seconds

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

The count of all encoded blocks received on this channel during this interval.

The count of all encoded blocks transmitted on this channel during this interval.

The count of all blocks received with errors that were corrected on this channel during this interval.

The count of all blocks received with uncorrectable errors on this channel during this interval.

The count of all encoded blocks received on this channel during this interval.

The count of all encoded blocks transmitted on this channel during this interval.

The count of all blocks received with errors that were corrected on this channel during this interval.

The count of all blocks received with uncorrectable errors on this channel during this interval.

For the each interval, adslAtucIntervalSesL reports the number of seconds during which there have been severely errored seconds-line. Unit: seconds

For the each interval, adslAtucIntervalUasL reports the number of seconds during which there have been unavailable seconds-line. Unit: seconds

For the each interval, adslAturIntervalSesL reports the number of seconds during which there have been severely errored seconds-line. Unit: seconds

For the each interval, adslAturIntervalUasL reports the number of seconds during which there have been unavailable seconds-line. Unit: seconds

Instantaneous value of the technology type that line is currently trained up under. Options: 1. adsl(1) - Indicates that line is currently trained up under adsl type 2. adsl2(2) - Indicates that line is currently trained up under adsl2 type 2. adsl2plus(3) - Indicates that line is currently trained up under adsl2+ type Enumeration: 'adsl2plus': 3, 'adsl': 1, 'adsl2': 2.

ADSL line rate change trap parameter table. The index of this table is ifIndex.

ADSL line rate change trap parameter table. The index of this entry is ifIndex.

The port IPIAID is reported when the port rate changes.

The port MUXID is reported when the port rate changes. Range: 0-20

The time stamp of Line rate change trap. Standard Unix format; as the number of seconds since 1/1/1970. Unit:Seconds.

Down stream line rate after line rate change.

Up stream line rate after line rate change.

Event type reported during the previous change of the rate If both the upstream and downstream rates change, this leaf outputs character string 'DU'. If only the upstream rates changes, this leaf outputs character string 'US'. If only the downstream rates changes, this leaf outputs character string 'DS'.

DSL line type of the port whose rate changes.

Enables or disables ADSL port line-rate change trap feature. Options: 1. enabled(1) - ADSL port line-rate change trap feature is enabled 2. disabled(2) - ADSL port line-rate change trap feature is disabled Enumeration: 'disabled': 2, 'enabled': 1.

Set the ADSL2 maximum interleaved depth function. Default values:maxInterleavedDepth511(2). Options: 1. maxInterleavedDepth64(1) - it means the interleaving depth up to 64 can be selected 2. maxInterleavedDepth511(2) - it means the interleaving depth up to 512 can be selected Enumeration: 'maxInterleavedDepth511': 2, 'maxInterleavedDepth64': 1.

Table of querying the performance statistics of the ATUC port. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The index of this table is ifIndex.

Table of querying the performance statistics of the ATUC port. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The index of this entry is ifIndex.

The count of the line initialization failed attempts since agent reset.

The count of the line initialization failed attempts in the current 15 minutes interval.

The count of the line initialization failed attempts in the day as measured by adslAtucPerfCurr1DayTimeElapsed.

The count of the line initialization failed attempts in the most recent previous 1-day period.

Count of the line initialization full attempts since agent reset.

Count of the line initialization full attempts in the current 15 minute interval.

Count of the line initialization full attempts in the day as measured by adslAtucPerfCurr1DayTimeElapsed.

Count of the line initialization full attempts in the most recent previous 1-day 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 current 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 current 15 minutes accumulation period. The near-end counter is only defined in upstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the current 15 minutes accumulation period. The near-end value is only defined in upstream.

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 current 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 current observed over the current 24 hours accumulation period. The near-end counter is only defined in upstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the current 24 hours accumulation period. The near-end value is only defined in upstream.

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

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the previous 24 hours accumulation period during this interval. The near-end counter is only defined in upstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the previous 24 hours accumulation period during this interval. The near-end value is only defined in upstream.

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. The near-end counter is only defined in upstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed ever before. The near-end value is only defined in upstream.

Start time of the current 15-minute performance statistics.

Start time of the current 1-day performance statistics.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during current 15 minutes. Each INMAINPEQ needs 4 bytes.

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. Each INMAIAT needs 4 bytes.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during current 1 day. Each INMAINPEQ needs 4 bytes.

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. Each INMAIAT needs 4 bytes.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during the most recent previous 1-day period. Each INMAINPEQ needs 4 bytes.

This parameter is a count of the INMAME anomalies occurring on the line during the most recent previous 1-day period.

This parameter is a count of the INMAIATi anomalies occurring on the line during the most recent previous 1-day period. Each INMAIAT needs 4 bytes.

This parameter is a count of the INMAINPEQi anomalies occurring on the line ever before. Each INMAINPEQ needs 4 bytes.

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. Each INMAIAT needs 4 bytes.

This table provides one row for each ATUC performance data collection interval. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The index of this table is ifIndex.

This table provides one row for each ATUC performance data collection interval. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The index of this entry is ifIndex.

The count of the line initialization failed attempts during the interval.

Count of the line initialization full attempts during the interval.

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 previous 15 minutes accumulation period during the interval.

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the previous 15 minutes accumulation period during the interval. The near-end counter is only defined in upstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the previous 15 minutes accumulation period during the interval. The near-end value is only defined in upstream.

Start time of the historical 15-minute performance statistics.

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

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

This parameter is a count of the INMAIATi anomalies occurring on the line at 15 minutes interval. Each INMAIAT needs 4 bytes.

Period table of collecting the ATUC channel performance data This table is used to query the ATUC channel performance data collected in each period (a day is divided into 96 15-minute periods). The indexes of this table are ifIndex and adslAtucChanIntervalNumber.

Period table of collecting the ATUC channel performance data This table is used to query the ATUC channel performance data collected in each period (a day is divided into 96 15-minute periods). The indexes of this entry are ifIndex and adslAtucChanIntervalNumber.

The count of all blocks received with FRC anomalies on this channel during this interval.

The count of all blocks received with HRC anomalies on this channel during this interval.

The count of all blocks received with CRC anomalies on this channel during this interval.

The count of units request retransmission on this channel during this interval.

The count of units corrected by retransmission on this channel during this interval.

The count of units uncorrected by retransmission on this channel during this interval.

Start time of the historical 15-minute performance statistics.

The table hwAdsl2SCStatusInfoTable contains status parameters of the ADSL2 sub-carriers. The indexes of this table are ifIndex and hwAdsl2SCStatusDirectionInfo.

The table hwAdsl2SCStatusInfoTable contains status parameters of the ADSL2 sub-carriers. The indexes of this entry are ifIndex and hwAdsl2SCStatusDirectionInfo.

The direction of the sub-carrier is either upstream or downstream. Options: 1. upstream(1) - The direction of the sub-carrier is upstream 2. downstream(2) - The direction of the sub-carrier is downstream Enumeration: 'downstream': 2, 'upstream': 1.

The SNR Margin per sub-carrier, expressing the ratio between the received signal power and received noise power per subscriber. It is an array of 512 octets, designed for supporting up to 512 (downstream) sub-carriers. The number of utilized octets on downstream direction depends on NSCds, and on upstream direction it depends on NSCus. This value is referred to here as NSC. Octet i (0 <= i < NSC) is set to a value in the range 0 to 254 to indicate that the respective downstream or upstream sub- carrier i has SNR of: (-32 + Adsl2SubcarrierSnr(i)/2) in dB (i.e., -32 to 95dB). The special value 255 means that no measurement could be done for the subcarrier because it is out of the PSD mask passband or that the noise PSD is out of range to be represented. Each value in this array is 8 bits wide.

The bits allocation per sub-carrier. An array of 256 octets (512 nibbles), designed for supporting up to 512 (downstream) sub-carriers. The number of utilized nibbles on downstream direction depends on NSCds, and on upstream direction it depends on NSCus. This value is referred to here as NSC. Nibble i (0 <= i < NSC) is set to a value in the range 0 to 15 to indicate that the respective downstream or upstream sub-carrier i has the same amount of bits allocation.

The gain allocation per sub-carrier. An array of 512 16-bits values, designed for supporting up to 512 (downstream) sub- carriers. The number of utilized octets on downstream direction depends on NSCds, and on upstream direction it depends on NSCus. This value is referred to here as NSC. Value i (0 <= i < NSC) is in the range 0 to 4093 to indicate that the respective downstream or upstream sub-carrier i has the same amount of gain value. The gain value is represented as a multiple of 1/512 on a linear scale. Each value in this array is 16 bits wide and is stored in big endian format.

An array of up to 512 real H(f) logarithmic representation values in dB for the respective transmission direction. It is designed to support up to 512 (downstream) sub-carriers. The number of utilized values on downstream direction depends on NSCds, and on upstream direction it depends on NSCus. This value is referred to here as NSC. Each array entry represents the real Hlog(f = i*Df) value for a particular sub-carrier index i, (0 <= i < NSC). The real Hlog(f) value is represented as (6-m(i)/10), with m(i) in the range 0 to 1022. A special value m=1023 indicates that no measurement could be done for the subcarrier because it is out of the passband or that the attenuation is out of range to be represented. This parameter is applicable in loop diagnostic procedure and initialization. Each value in this array is 16 bits wide and is stored in big endian format.

An array of up to 512 real Quiet Line Noise values in dBm/Hz for the respective transmission direction. It is designed for up to 512 (downstream) sub-carriers. The number of utilized values on downstream direction depends on NSCds, and on upstream direction it depends on NSCus. This value is referred to here as NSC. Each array entry represents the QLN(f = i*Df) value for a particular sub-carrier index i, (0 <= i < NSC). The QLN(f) is represented as (-23-n(i)/2), with n(i) in the range 0 to 254. A special value n(i)=255 indicates that no measurement could be done for the subcarrier because it is out of the passband or that the noise PSD is out of range to be represented. This parameter is applicable in loop diagnostic procedure and initialization. Each value in this array is 8 bits wide.

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).

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)

This table includes common parameters of the xDSL Dynamic profile. The index of this table is hwxdslDynamicProfProfileNameCfg.

This table includes common parameters of the xDSL Dynamic profile. The index of this entry is hwxdslDynamicProfProfileNameCfg.

The name of xDSL Dynamic Profile.

XTU Transmission System Enabling (ATSE). A list of the different coding types enabled in this profile. It is coded in a bit-map representation with 1 or more bits set. A bit set to '1' means that the XTUs may apply the respective coding for the xDSL line. A bit set to '0' means that the XTUs cannot apply the respective coding for the XDSL line. All 'reserved' bits should be set to '0'. Bits: 'reserved11': 45, 'g9925PotsNonOverlapped': 40, 'g9922tcmIsdnNonOverlapped': 10, 'g9923AnnexJAllDigNonOverlapped': 30, 'reserved29': 69, 'g9925AnnexMPotsNonOverlapped': 50, 'g9925AnnexIAllDigOverlapped': 47, 'g9925PotsOverlapped': 41, 'g9921tcmIsdnNonOverlapped': 6, 'g9922potsNonOverlapped': 8, 'g9923PotsNonOverlapped': 18, 'reserved9': 27, 'reserved8': 26, 'g9921tcmIsdnOverlapped': 7, 'reserved5': 17, 'reserved4': 16, 'reserved7': 23, 'reserved6': 22, 'reserved1': 13, 'g9923IsdnNonOverlapped': 20, 'reserved3': 15, 'g9923PotsOverlapped': 19, 'g9923isdnOverlapped': 21, 'g9923AnnexLMode1NonOverlapped': 34, 'g9921IsdnNonOverlapped': 4, 'reserved12': 52, 'g9924potsOverlapped': 25, 'g9921PotsNonOverlapped': 2, 'g9932AnnexAPots': 72, 'g9923AnnexMPotsOverlapped': 39, 'g9923AnnexJAllDigOverlapped': 31, 'g9924potsNonOverlapped': 24, 'g9923AnnexLMode2NonOverlapped': 35, 'g9932AnnexBIsdn': 75, 'g9932AnnexAIsdn': 73, 'reserved18': 58, 'g9921isdnOverlapped': 5, 'g9925AnnexMPotsOverlapped': 51, 'reserved32': 78, 'reserved31': 71, 'reserved30': 70, 'reserved15': 55, 'reserved14': 54, 'reserved17': 57, 'reserved16': 56, 'g9924AnnexIAllDigOverlapped': 33, 'reserved10': 44, 'reserved13': 53, 'g9925isdnOverlapped': 43, 'reserved19': 59, 'etsi': 1, 'g9923AnnexLMode3Overlapped': 36, 'ansit1413': 0, 'g9922potsOverlapped': 9, 'g9922tcmIsdnOverlapped': 11, 'g9925AnnexIAllDigNonOverlapped': 46, 'g9932AnnexCIsdn': 77, 'g9925AnnexJAllDigNonOverlapped': 48, 'g9923AnnexIAllDigNonOverlapped': 28, 'g9923AnnexMPotsNonOverlapped': 38, 'g9923AnnexIAllDigOverlapped': 29, 'reserved2': 14, 'g9932AnnexBPots': 74, 'reserved33': 79, 'g9932AnnexCPots': 76, 'g9925IsdnNonOverlapped': 42, 'g9925AnnexJAllDigOverlapped': 49, 'reserved28': 68, 'g9921PotsOverlapped': 3, 'g9921tcmIsdnSymmetric': 12, 'g9924AnnexIAllDigNonOverlapped': 32, 'g9923AnnexLMode4Overlapped': 37, 'reserved20': 60, 'reserved21': 61, 'reserved22': 62, 'reserved23': 63, 'reserved24': 64, 'reserved25': 65, 'reserved26': 66, 'reserved27': 67.

Enables or disables the bit swap downstream of a line. Options: 1. disable(1) - The bit swap downstream of a line is disabled 2. enable(2) - The bit swap downstream of a line is enabled 3. invalidValue(-1) - Invalid value Enumeration: 'enable': 2, 'invalidValue': -1, 'disable': 1.

Enables or disables the bit swap upstream of a line. Options: 1. disable(1) - The bit swap upstream of a line is disabled 2. enable(2) - The bit swap upstream of a line is enabled 3. invalidValue(-1) - Invalid value Enumeration: 'enable': 2, 'invalidValue': -1, 'disable': 1.

The target Noise Margin the xTU-R receiver shall achieve, relative to the BER requirement for each of the downstream bearer channels, to successfully complete initialization. The target noise margin ranges from 0 to 310 units of 0.1 dB (Physical values are 0 to 31 dB). Range: 0-310 Unit: 0.1 dB

The target Noise Margin the xTU-C receiver shall achieve, relative to the BER requirement for each of the downstream bearer channels, to successfully complete initialization. The target noise margin ranges from 0 to 310 units of 0.1 dB (Physical values are 0 to 31 dB). Range: 0-310 Unit: 0.1 dB

The maximum Noise Margin the xTU-R receiver shall achieve, relative to the BER requirement for each of the downstream bearer channels, to successfully complete initialization. The target noise margin ranges from 0 to 310 units of 0.1 dB (Physical values are 0 to 31 dB). Range: 0-310 Unit: 0.1 dB

The maximum Noise Margin the xTU-C receiver shall achieve, relative to the BER requirement for each of the downstream bearer channels, to successfully complete initialization. The target noise margin ranges from 0 to 310 units of 0.1 dB (Physical values are 0 to 31 dB). Range: 0-310 Unit: 0.1 dB

The minimum Noise Margin the xTU-R receiver shall achieve, relative to the BER requirement for each of the downstream bearer channels, to successfully complete initialization. The target noise margin ranges from 0 to 310 units of 0.1 dB (Physical values are 0 to 31 dB). Range: 0-310 Unit: 0.1 dB

The minimum Noise Margin the xTU-C receiver shall achieve, relative to the BER requirement for each of the downstream bearer channels, to successfully complete initialization. The target noise margin ranges from 0 to 310 units of 0.1 dB (Physical values are 0 to 31 dB). Range: 0-310 Unit: 0.1 dB

Minimum Impulse Noise Protection on Downstream direction. The minimum impulse noise protection for the bearer channel, expressed in symbols. The parameter can take the following values: noProtection (i.e., INP not required), halfSymbol (i.e., INP length is 1/2 symbol) and 1-16 symbols in steps of 1 symbol. Options: 1. noProtection (1) - Indicates that the INP value is 0 2. halfSymbol (2) - Indicates that the INP value is 0.5 3. singleSymbol (3) - Indicates that the INP value is 1 4. twoSymbols (4) - Indicates that the INP value is 2 5. threeSymbols (5) - Indicates that the INP value is 3 6. fourSymbols (6) - Indicates that the INP value is 4 7. fiveSymbols (7) - Indicates that the INP value is 5 8. sixSymbols (8) - Indicates that the INP value is 6 9. sevenSymbols (9) - Indicates that the INP value is 7 10. eightSymbols (10) - Indicates that the INP value is 8 11. nineSymbols (11) - Indicates that the INP value is 9 12. tenSymbols (12) - Indicates that the INP value is 10 13. elevenSymbols (13) - Indicates that the INP value is 11 14. twelveSymbols (14) - Indicates that the INP value is 12 15. thirteenSymbols (15) - Indicates that the INP value is 13 16. fourteenSymbols (16) - Indicates that the INP value is 14 17. fifteenSymbols (17) - Indicates that the INP value is 15 18. sixteenSymbols (18) - Indicates that the INP value is 16 19. invalidValue(-1) - Invalid value Enumeration: 'fourSymbols': 6, 'thirteenSymbols': 15, 'invalidValue': -1, 'sixSymbols': 8, 'fifteenSymbols': 17, 'noProtection': 1, 'fiveSymbols': 7, 'sevenSymbols': 9, 'eightSymbols': 10, 'fourteenSymbols': 16, 'nineSymbols': 11, 'threeSymbols': 5, 'singleSymbol': 3, 'halfSymbol': 2, 'tenSymbols': 12, 'twoSymbols': 4, 'twelveSymbols': 14, 'sixteenSymbols': 18, 'elevenSymbols': 13.

Minimum Impulse Noise Protection on Upstream direction. The minimum impulse noise protection for the bearer channel, expressed in symbols. The parameter can take the following values: noProtection (i.e., INP not required), halfSymbol (i.e., INP length is 1/2 symbol) and 1-16 symbols in steps of 1 symbol. Options: 1. noProtection (1) - Indicates that the INP value is 0 2. halfSymbol (2) - Indicates that the INP value is 0.5 3. singleSymbol (3) - Indicates that the INP value is 1 4. twoSymbols (4) - Indicates that the INP value is 2 5. threeSymbols (5) - Indicates that the INP value is 3 6. fourSymbols (6) - Indicates that the INP value is 4 7. fiveSymbols (7) - Indicates that the INP value is 5 8. sixSymbols (8) - Indicates that the INP value is 6 9. sevenSymbols (9) - Indicates that the INP value is 7 10. eightSymbols (10) - Indicates that the INP value is 8 11. nineSymbols (11) - Indicates that the INP value is 9 12. tenSymbols (12) - Indicates that the INP value is 10 13. elevenSymbols (13) - Indicates that the INP value is 11 14. twelveSymbols (14) - Indicates that the INP value is 12 15. thirteenSymbols (15) - Indicates that the INP value is 13 16. fourteenSymbols (16) - Indicates that the INP value is 14 17. fifteenSymbols (17) - Indicates that the INP value is 15 18. sixteenSymbols (18) - Indicates that the INP value is 16 19. invalidValue(-1) - Invalid value Enumeration: 'fourSymbols': 6, 'thirteenSymbols': 15, 'invalidValue': -1, 'sixSymbols': 8, 'fifteenSymbols': 17, 'noProtection': 1, 'fiveSymbols': 7, 'sevenSymbols': 9, 'eightSymbols': 10, 'fourteenSymbols': 16, 'nineSymbols': 11, 'threeSymbols': 5, 'singleSymbol': 3, 'halfSymbol': 2, 'tenSymbols': 12, 'twoSymbols': 4, 'twelveSymbols': 14, 'sixteenSymbols': 18, 'elevenSymbols': 13.

Maximum Interleave Delay on Downstream direction. The maximum one-way interleaving delay introduced by the PMS-TC on Downstream direction. The XTUs shall choose the S (factor) and D (depth) values such that the actual one-way interleaving delay is as close as possible to, but less than or equal to, hwxdslDynamicProfCh1MaxDelayDs. The delay is coded in ms, with the value 0 indicating no delay bound is being imposed. Range: 0-200 Unit: milliseconds

Maximum Interleave Delay on Upstream direction. The maximum one-way interleaving delay introduced by the PMS-TC on Upstream direction. The XTUs shall choose the S (factor) and D (depth) values such that the actual one-way interleaving delay is as close as possible to, but less than or equal to, hwxdslDynamicProfCh1MaxDelayUs. The delay is coded in ms, with the value 0 indicating no delay bound is being imposed. Range: 0-200 Unit: milliseconds

Minimum Impulse Noise Protection on Downstream direction. The minimum impulse noise protection for the bearer channel, expressed in symbols. The parameter can take the following values: noProtection (i.e., INP not required), halfSymbol (i.e., INP length is 1/2 symbol) and 1-16 symbols in steps of 1 symbol. Options: 1. noProtection (1) - Indicates that the INP value is 0 2. halfSymbol (2) - Indicates that the INP value is 0.5 3. singleSymbol (3) - Indicates that the INP value is 1 4. twoSymbols (4) - Indicates that the INP value is 2 5. threeSymbols (5) - Indicates that the INP value is 3 6. fourSymbols (6) - Indicates that the INP value is 4 7. fiveSymbols (7) - Indicates that the INP value is 5 8. sixSymbols (8) - Indicates that the INP value is 6 9. sevenSymbols (9) - Indicates that the INP value is 7 10. eightSymbols (10) - Indicates that the INP value is 8 11. nineSymbols (11) - Indicates that the INP value is 9 12. tenSymbols (12) - Indicates that the INP value is 10 13. elevenSymbols (13) - Indicates that the INP value is 11 14. twelveSymbols (14) - Indicates that the INP value is 12 15. thirteenSymbols (15) - Indicates that the INP value is 13 16. fourteenSymbols (16) - Indicates that the INP value is 14 17. fifteenSymbols (17) - Indicates that the INP value is 15 18. sixteenSymbols (18) - Indicates that the INP value is 16 19. invalidValue(-1) - Invalid value Enumeration: 'fourSymbols': 6, 'thirteenSymbols': 15, 'invalidValue': -1, 'sixSymbols': 8, 'fifteenSymbols': 17, 'noProtection': 1, 'fiveSymbols': 7, 'sevenSymbols': 9, 'eightSymbols': 10, 'fourteenSymbols': 16, 'nineSymbols': 11, 'threeSymbols': 5, 'singleSymbol': 3, 'halfSymbol': 2, 'tenSymbols': 12, 'twoSymbols': 4, 'twelveSymbols': 14, 'sixteenSymbols': 18, 'elevenSymbols': 13.

Minimum Impulse Noise Protection on Upstream direction. The minimum impulse noise protection for the bearer channel, expressed in symbols. The parameter can take the following values: noProtection (i.e., INP not required), halfSymbol (i.e., INP length is 1/2 symbol) and 1-16 symbols in steps of 1 symbol. Options: 1. noProtection (1) - Indicates that the INP value is 0 2. halfSymbol (2) - Indicates that the INP value is 0.5 3. singleSymbol (3) - Indicates that the INP value is 1 4. twoSymbols (4) - Indicates that the INP value is 2 5. threeSymbols (5) - Indicates that the INP value is 3 6. fourSymbols (6) - Indicates that the INP value is 4 7. fiveSymbols (7) - Indicates that the INP value is 5 8. sixSymbols (8) - Indicates that the INP value is 6 9. sevenSymbols (9) - Indicates that the INP value is 7 10. eightSymbols (10) - Indicates that the INP value is 8 11. nineSymbols (11) - Indicates that the INP value is 9 12. tenSymbols (12) - Indicates that the INP value is 10 13. elevenSymbols (13) - Indicates that the INP value is 11 14. twelveSymbols (14) - Indicates that the INP value is 12 15. thirteenSymbols (15) - Indicates that the INP value is 13 16. fourteenSymbols (16) - Indicates that the INP value is 14 17. fifteenSymbols (17) - Indicates that the INP value is 15 18. sixteenSymbols (18) - Indicates that the INP value is 16 19. invalidValue(-1) - Invalid value Enumeration: 'fourSymbols': 6, 'thirteenSymbols': 15, 'invalidValue': -1, 'sixSymbols': 8, 'fifteenSymbols': 17, 'noProtection': 1, 'fiveSymbols': 7, 'sevenSymbols': 9, 'eightSymbols': 10, 'fourteenSymbols': 16, 'nineSymbols': 11, 'threeSymbols': 5, 'singleSymbol': 3, 'halfSymbol': 2, 'tenSymbols': 12, 'twoSymbols': 4, 'twelveSymbols': 14, 'sixteenSymbols': 18, 'elevenSymbols': 13.

Maximum Interleave Delay on Downstream direction. The maximum one-way interleaving delay introduced by the PMS-TC on Downstream direction. The XTUs shall choose the S (factor) and D (depth) values such that the actual one-way interleaving delay is as close as possible to, but less than or equal to, hwxdslDynamicProfCh2MaxDelayDs. The delay is coded in ms, with the value 0 indicating no delay bound is being imposed. Range: 0-200 Unit: milliseconds

Maximum Interleave Delay on Upstream direction. The maximum one-way interleaving delay introduced by the PMS-TC on Upstream direction. The XTUs shall choose the S (factor) and D (depth) values such that the actual one-way interleaving delay is as close as possible to, but less than or equal to, hwxdslDynamicProfCh2MaxDelayUs. The delay is coded in ms, with the value 0 indicating no delay bound is being imposed. Range: 0-200 Unit: milliseconds

Power management state Enabling. Defines the power states the xTU-C or xTU-R may autonomously transition to on this line. The various bit positions are: allowTransitionsToIdle (0) and allowTransitionsToLowPower (1). A bit with a '1' value means that the xTU is allowed to transit into the respective state and a '0' value means that the xTU is not allowed to transit into the respective state. Bits: 'allowTransitionsToLowPower': 1, 'allowTransitionsToIdle': 0.

This minimum time (in seconds) between an exit from the L2 state and the next Entry into the L2 state. It ranges from 0 to 255 seconds. Range: 0-255

This minimum time (in seconds) between an entry into the L2 state and the first power trim in the L2 state and between two consecutive power trims in the L2 State. It ranges from 0 to 255 seconds. Range: 0-255

The maximum aggregate transmit power reduction (in dB) that can be performed at transition of L0 to L2 state or through a single power trim in the L2 state. It ranges from 0 dB to 31 dB. Range: 0-31 Unit: dB

The total maximum aggregate transmit power reduction (in dB) that can be performed in an L2 state. This is the sum of all reductions of L2 Request (i.e., at transition of L0 to L2 state) and power trims. Range: 0-31 Unit: dB

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. Range: 0-511 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. Octets 0+1 DPBOESCMA Octets 2+3 DPBOESCMB Octets 4+5 DPBOESCMC

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. Range: 0-255 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). Range: 0-2048 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). Range: 32-6956 Unit: 4.3125 KHz

This parameter defines the UPBO reference PSD used to compute the upstream power back-off for each upstream band except US0. A UPBOPSD defined for each band ahsll consist of two parameters [a, b]. Parameter a shall be coded as an unsigned 12-bit number from 40 dBm/Hz (coded as 0) to 80.95 dBm/Hz (coded as 4095) in steps of 0.01 dBm/Hz; and b shall be coded as an unsigned 12 bit number from 0 (coded as 0) to 40.95 dBm/Hz (coded as 4095) in steps of 0.01 dBm/Hz. The UPBO reference PSD at the frequency f expressed in MHz shall be equal to '-a-b(SQRT(f))'. The set of parameter values a = 40 dBm/Hz, b = 0 dBm/Hz is a special configuration to disable UPBO in the respective upstream band. Octets 0+1 - a[0] Octets 2+3 - b[0] Octets 4+5 - a[1] Octets 6+7 - b[1] Octets 8+9 - a[2] Octets 10+11 - b[2] Octets 12+13 - a[3] Octets 14+15 - b[3]

This parameter is a flag that forces the VTU-R to use the electrical loop length of the CO-MIB (UPBOKL) to compute the UPBO. The value shall be forced if the flag is set to 1. Otherwise, the electrical loop length shall be autonomously selected by the VTU-O. Options: 1. forced(1) - Force the CPE to use the electrical length of the CO(UPBOKL) to compute the UPBO 2. auto(2) - Electrical length shall be autonomously selected by the CO 3. invalidValue(-1) - Invalid value Enumeration: 'forced': 1, 'invalidValue': -1, 'auto': 2.

This parameter defines the electrical loop length expressed in dB at 1MHz, kl0, configured by the CO-MIB. The value shall be coded as an unsigned 16 bit number in the range 0 (coded as 0) to 128 dB (coded as 1280) in steps of 0.1 dB. Range: 0-1280 Unit: 0.1 dB

The subset of PSD mask breakpoints that shall be used to notch an RFI band. It is a string of bands consist of begin tone index and end tone index. for example :0-10,20-50,100-4095 It can contain as most as 16 bands.

The subset of subcarriermask that shall be used to mask the subcarriers. It is a string of bands consist of begin tone index and end tone index. For example :0-10,20-50,100-4095. It can contain as most as 8 bands.

Sub-carriers mask. A bitmap of 512 bits that allows masking up to 512 downstream sub-carriers, depending on NSCds. If bit i (0 <= i < NSCds) is set to '1', the respective downstream sub-carrier i is masked, and if set to '0', the respective sub-carrier is unmasked. Note that there should always be unmasked sub-carriers (i.e., the object cannot be all 1's). Also note that if NSCds < 512, all bits i (NSCds i <= 512) should be set to '1'.

Sub-carriers mask. A bitmap of 64 bits that allows masking up to 64 downstream sub-carriers, depending on NSCds. If bit i (0 <= i < NSCus) is set to '1', the respective upstream sub-carrier i is masked, and if set to '0', the respective sub-carrier is unmasked. Note that there should always be unmasked sub-carriers (i.e., the object cannot be all 1's). Also note that if NSCus < 64, all bits i (NSCus < i <= 64) should be set to '1'.

The xDSL mode is a way of categorizing the various XDSL transmission modes into groups, each group (XDSL Mode) shares the same PSD configuration. Options: 1. defMode (1) - XDSL transmit mode is defMode 2. adsl (2) - XDSL transmit mode is adsl 3. adsl2Pots (3) - XDSL transmit mode is adsl2Pots 4. adsl2Isdn (4) - XDSL transmit mode is adsl2Isdn 5. adsl2PlusPots (5) - XDSL transmit mode is adsl2PlusPots 6. adsl2PlusIsdn (6) - XDSL transmit mode is adsl2PlusIsdn 7. adsl2ReachExtended (7) - XDSL transmit mode is adsl2ReachExtended 8. g9923PotsNonOverlapped(8) - XDSL transmit mode is g9923PotsNonOverlapped 9. g9923PotsOverlapped(9) - XDSL transmit mode is g9923PotsOverlapped 10. g9923IsdnNonOverlapped(10) - XDSL transmit mode is g9923IsdnNonOverlapped 11. g9923isdnOverlapped(11) - XDSL transmit mode is g9923isdnOverlapped 12. g9924potsNonOverlapped(14) - XDSL transmit mode is g9924potsNonOverlapped 13. g9924potsOverlapped(15) - XDSL transmit mode is g9924potsOverlapped 14. g9923AnnexIAllDigNonOverlapped(18) - XDSL transmit mode is g9923AnnexIAllDigNonOverlapped 15. g9923AnnexIAllDigOverlapped(19) - XDSL transmit mode is g9923AnnexIAllDigOverlapped 16. g9923AnnexJAllDigNonOverlapped(20) - XDSL transmit mode is g9923AnnexJAllDigNonOverlapped 17. g9923AnnexJAllDigOverlapped(21) - XDSL transmit mode is g9923AnnexJAllDigOverlapped 18. g9924AnnexIAllDigNonOverlapped(22) - XDSL transmit mode is g9924AnnexIAllDigNonOverlapped 19. g9924AnnexIAllDigOverlapped(23) - XDSL transmit mode is g9924AnnexIAllDigOverlapped 20. g9923AnnexLMode1NonOverlapped(24) - XDSL transmit mode is g9923AnnexLMode1NonOverlapped 21. g9923AnnexLMode2NonOverlapped(25) - XDSL transmit mode is g9923AnnexLMode2NonOverlapped 22. g9923AnnexLMode3Overlapped(26) - XDSL transmit mode is g9923AnnexLMode3Overlapped 23. g9923AnnexLMode4Overlapped(27) - XDSL transmit mode is g9923AnnexLMode4Overlapped 24. g9923AnnexMPotsNonOverlapped(28) - XDSL transmit mode is g9923AnnexMPotsNonOverlapped 25. g9923AnnexMPotsOverlapped(29) - XDSL transmit mode is g9923AnnexMPotsOverlapped 26. g9925PotsNonOverlapped(30) - XDSL transmit mode is g9925PotsNonOverlapped 27. g9925PotsOverlapped(31) - XDSL transmit mode is g9925PotsOverlapped 28. g9925IsdnNonOverlapped(32) - XDSL transmit mode is g9925IsdnNonOverlapped 29. g9925isdnOverlapped(33) - XDSL transmit mode is g9925isdnOverlapped 30. g9925AnnexIAllDigNonOverlapped(36) - XDSL transmit mode is g9925AnnexIAllDigNonOverlapped 31. g9925AnnexIAllDigOverlapped(37) - XDSL transmit mode is g9925AnnexIAllDigOverlapped 32. g9925AnnexJAllDigNonOverlapped(38) - XDSL transmit mode is g9925AnnexJAllDigNonOverlapped 33. g9925AnnexJAllDigOverlapped(39) - XDSL transmit mode is g9925AnnexJAllDigOverlapped 34. g9925AnnexMPotsNonOverlapped(40) - XDSL transmit mode is g9925AnnexMPotsNonOverlapped 35. g9925AnnexMPotsOverlapped(41) - XDSL transmit mode is g9925AnnexMPotsOverlapped 36. vdsl2Pots (42) - XDSL transmit mode is vdsl2Pots 37. vdsl2Isdn (43) - XDSL transmit mode is vdsl2Isdn 38. invalidValue(-1) - Invalid value Enumeration: 'g9925PotsNonOverlapped': 30, 'g9923PotsNonOverlapped': 8, 'g9923AnnexJAllDigNonOverlapped': 20, 'g9925AnnexMPotsNonOverlapped': 40, 'g9923AnnexIAllDigNonOverlapped': 18, 'g9925AnnexIAllDigOverlapped': 37, 'adsl': 2, 'g9923IsdnNonOverlapped': 10, 'g9924potsNonOverlapped': 14, 'g9923PotsOverlapped': 9, 'g9923isdnOverlapped': 11, 'g9923AnnexLMode1NonOverlapped': 24, 'adsl2Pots': 3, 'adsl2Isdn': 4, 'g9924potsOverlapped': 15, 'g9925PotsOverlapped': 31, 'g9923AnnexMPotsOverlapped': 29, 'g9923AnnexJAllDigOverlapped': 21, 'g9925AnnexMPotsOverlapped': 41, 'vdsl2Pots': 42, 'g9924AnnexIAllDigOverlapped': 23, 'g9925isdnOverlapped': 33, 'g9925AnnexJAllDigOverlapped': 39, 'g9923AnnexLMode3Overlapped': 26, 'g9923AnnexLMode2NonOverlapped': 25, 'g9925AnnexIAllDigNonOverlapped': 36, 'g9925AnnexJAllDigNonOverlapped': 38, 'defMode': 1, 'g9923AnnexMPotsNonOverlapped': 28, 'g9923AnnexIAllDigOverlapped': 19, 'invalidValue': -1, 'g9925IsdnNonOverlapped': 32, 'adsl2ReachExtended': 7, 'adsl2PlusPots': 5, 'adsl2PlusIsdn': 6, 'g9924AnnexIAllDigNonOverlapped': 22, 'g9923AnnexLMode4Overlapped': 27, 'vdsl2Isdn': 43.

The maximum nominal transmit PSD in the downstream direction during initialization and show time. It ranges from -600 to -300 units of 0.1 dBm/Hz(physical values are -60 to -30 dBm/Hz). The invalid value is -1. If data is invalid, the invalid value will be returned. Unit: 0.1 dB

The maximum nominal transmit PSD in the upstream direction during initialization and show time. It ranges from -600 to -300 units of 0.1 dBm/Hz(physical values are -60 to -30 dBm/Hz). The invalid value is -1. If data is invalid, the invalid value will be returned. Unit: 0.1 dB

The maximum nominal aggregate transmit power in the downstream direction during initialization and show time. It ranges from 0 to 255 units of 0.1 dBm (physical values are 0 to 25.5 dBm). Range: 0-255 Unit: 0.1 dBm

The maximum nominal aggregate transmit power in the upstream direction during initialization and show time. It ranges from 0 to 255 units of 0.1 dBm (physical values are 0 to 25.5 dBm). Range: 0-255 Unit: 0.1 dBm

This configuration parameter defines the downstream PSD mask applicable at the U C2 reference point. This MIB PSD mask may impose PSD restrictions in addition to the Limit PSD mask defined in the relevant Recommendation (e.g., G.992.5, G.993.2). This is a string of 32 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 94-95, which are associated with a 32nd breakpoint. Each subcarrier index is an unsigned number in the range 0 and (NSCds - 1). 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 32, all remaining octets are set to the value 0xff. Note that the content of this object should be correlated with the sub-carriers mask and with the RFI setup.

This configuration parameter defines the upstream PSD mask applicable at the U R2 reference point. This MIB PSD mask may impose PSD restrictions in addition to the Limit PSD mask defined in the relevant Recommendations (e.g., ITU-T Recommendations G.992.3, G.993.2). 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 45-47 - 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 0 and (NSCus - 1). 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. Note that the content of this object should be correlated with the sub-carriers mask and with the RFI setup.

This configuration parameter contains the G.993.2 profiles to be allowed by the near-end xTU on this line. Options: 1. profile8a (1) - The G.993.2 profile is profile8a 2. profile8b (2) - The G.993.2 profile is profile8b 3. profile8c (3) - The G.993.2 profile is profile8c 4. profile8d (4) - The G.993.2 profile is profile8d 5. profile12a (5) - The G.993.2 profile is profile12a 6. profile12b (6) - The G.993.2 profile is profile12b 7. profile17a (7) - The G.993.2 profile is profile17a 8. profile30a (8) - The G.993.2 profile is profile30a 9. invalidValue(-1) - Invalid value Enumeration: 'invalidValue': -1, 'profile12a': 5, 'profile8d': 4, 'profile8b': 2, 'profile30a': 8, 'profile8a': 1, 'profile8c': 3, 'profile12b': 6, 'profile17a': 7.

In order to reduce the number of configuration possibilities, the limit PSD masks are grouped in the following PSD mask classes: Options: 1. annexA998-D-32(1) - Class 998 Annex A: D-32, D-64, D-48, D-128 2. annexA998-D-64(2) - Class 998 Annex A: D-32, D-64, D-48, D-128 3. annexB997-M1c-A-7(3) - Class 997-M1c Annex B: 997-M1c-A-7 4. annexB997-M1x-M-8(4) - Class 997-M1x Annex B: 997-M1x-M-8, 997-M1x-M 5. annexB997-M1x-M(5) - Class 997-M1x Annex B: 997-M1x-M-8, 997-M1x-M 6. annexB997-M2x-M-8(6) - Class 997-M2x Annex B: 997-M2x-M-8, 997-M2x-A, 997-M2x-M 7. annexB997-M2x-A(7) - Class 997-M2x Annex B: 997-M2x-M-8, 997-M2x-A, 997-M2x-M 8. annexB997-M2x-M(8) - Class 997-M2x Annex B: 997-M2x-M-8, 997-M2x-A, 997-M2x-M 9. annexB998-M1x-A(9) - Class 998-M1x Annex B: 998-M1x-A, 998-M1x-B, 998-M1x-NUS0 10. annexB998-M1x-B(10) - Class 998-M1x Annex B: 998-M1x-A, 998-M1x-B, 998-M1x-NUS0 11. annexB998-M1x-NUS0(11) - Class 998-M1x Annex B: 998-M1x-A, 998-M1x-B, 998-M1x-NUS0 12. annexB998-M2x-A(12) - Class 998-M2x Annex B: 998-M2x-A, 998-M2x-M, 998-M2x-B, 998-M2x-NUS0 13. annexB998-M2x-M(13) - Class 998-M2x Annex B: 998-M2x-A, 998-M2x-M, 998-M2x-B, 998-M2x-NUS0 14. annexB998-M2x-B(14) - Class 998-M2x Annex B: 998-M2x-A, 998-M2x-M, 998-M2x-B, 998-M2x-NUS0 15. annexB998-M2x-NUS0(15) - Class 998-M2x Annex B: 998-M2x-A, 998-M2x-M, 998-M2x-B, 998-M2x-NUS0 16. annexBHPE17-M1(16) - Class HPE17 Annex B: HPE17-M1 17. annexBHPE30-M1(17) - Class HPE30 Annex B: HPE30-M1 18. annexB997E17-M2x-A(18) - Class 997E17-M2x Annex B: 997E17-M2x-A 19. annexB997E30-M2x-NUS0(19) - Class 997E30-M2x Annex B: 997E30-M2x-NUS0 20. annexB998E17-M2x-NUS0(20) - Class 998E17-M2x Annex B: 998E17-M2x-NUS0, 998E17-M2x-NUS0-M 21. annexB998E17-M2x-NUS0-M(21) - Class 998E17-M2x Annex B: 998E17-M2x-NUS0, 998E17-M2x-NUS0-M 22. annexB998ADE17-M2x-NUS0-M(22) - Class 998ADE17-M2x Annex B: 998ADE17-M2x-NUS0-M, 998ADE17-M2x-A, 998ADE17-M2x-B, 998ADE17-M2x-M. 23. annexB998ADE17-M2x-B(23) - Class 998ADE17-M2x Annex B: 998ADE17-M2x-NUS0-M, 998ADE17-M2x-A, 998ADE17-M2x-B, 998ADE17-M2x-M. 24. annexB998E30-M2x-NUS0(24) - Class 998E30-M2x Annex B: 998E30-M2x-NUS0, 998E30-M2x-NUS0-M 25. annexB998E30-M2x-NUS0-M(25) - Class 998E30-M2x Annex B: 998E30-M2x-NUS0, 998E30-M2x-NUS0-M 26. annexB998ADE30-M2x-NUS0-M(26) - Class 998ADE30-M2x Annex B: 998ADE30-M2x-NUS0-M, 998ADE30-M2x-NUS0-A 27. annexB998ADE17-M2x-A(27) - Class 998ADE17-M2x Annex B: 998ADE17-M2x-NUS0-M, 998ADE17-M2x-A, 998ADE17-M2x-B, 998ADE17-M2x-M. 28. annexB998ADE30-M2x-NUS0-A(28) - Class 998ADE30-M2x Annex B: 998ADE30-M2x-NUS0-M, 998ADE30-M2x-NUS0-A 29. annexA998-D-48(29) - Class 998 Annex A: D-32, D-64, D-48, D-128 30. annexA998-D-128(30) - Class 998 Annex A: D-32, D-64, D-48, D-128 31. annexB998ADE17-M2x-M(31) - Class 998ADE17-M2x Annex B: 998ADE17-M2x-NUS0-M, 998ADE17-M2x-A, 998ADE17-M2x-B, 998ADE17-M2x-M. 32. invalidValue(-1) - Invalid value Enumeration: 'annexB998E30-M2x-NUS0-M': 25, 'annexA998-D-32': 1, 'annexB998-M1x-NUS0': 11, 'annexB997E17-M2x-A': 18, 'annexB998-M2x-M': 13, 'annexB998E30-M2x-NUS0': 24, 'annexBHPE17-M1': 16, 'annexB998-M2x-B': 14, 'annexB998-M2x-A': 12, 'annexB997-M2x-M-8': 6, 'annexB998E17-M2x-NUS0-M': 21, 'annexB998-M1x-B': 10, 'annexA998-D-48': 29, 'annexB998ADE17-M2x-NUS0-M': 22, 'annexA998-D-128': 30, 'annexB997-M1x-M': 5, 'annexB998-M2x-NUS0': 15, 'annexA998-D-64': 2, 'annexB997-M1c-A-7': 3, 'annexB998ADE17-M2x-A': 27, 'annexBHPE30-M1': 17, 'annexB998ADE17-M2x-B': 23, 'annexB997-M1x-M-8': 4, 'annexB997-M2x-A': 7, 'annexB998ADE17-M2x-M': 31, 'annexB998ADE30-M2x-NUS0-A': 28, 'annexB998-M1x-A': 9, 'annexB997E30-M2x-NUS0': 19, 'invalidValue': -1, 'annexB998ADE30-M2x-NUS0-M': 26, 'annexB997-M2x-M': 8, 'annexB998E17-M2x-NUS0': 20.

Defines the VDSL link use of the optional frequency range [25kHz - 138kHz] (Opt). Options: 1. disable(1) - Indicates Opt is unused 2. enable(2) - Indicates Opt usage is for upstream 3. invalidValue(-1) - Invalid value Huawei defined. Enumeration: 'enable': 2, 'invalidValue': -1, 'disable': 1.

Defines the Virtual Noise of downsteam. Options: 1. disable(1) -unused 2. enable(2) -used 3. invalidValue(-1) -invalid Value Huawei defined. Enumeration: 'enable': 2, 'invalidValue': -1, 'disable': 1.

Defines the Virtual Noise of upstream. Options: 1. disable(1) -unused 2. enable(2) -used 3. invalidValue(-1) -invalid Value Huawei defined. Enumeration: 'enable': 2, 'invalidValue': -1, 'disable': 1.

The Virtual Noise of downsteam. This is a string of 32 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 94-95, which are associated with a 32nd breakpoint. Each subcarrier index is an unsigned number in the range 0 and (NSCds - 1). Each PSD reduction value is in the range 0 (0dBm/Hz) to 255 (127.5dBm/Hz) with steps of 0.5dBm/Hz.

The Virtual Noise of upsteam. 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 0 and (NSCds - 1). Each PSD reduction value is in the range 0 (0dBm/Hz) to 255 (127.5dBm/Hz) with steps of 0.5dBm/Hz.

This object is used to create a new row or to modify or delete an existing row in this table. A profile is activated by setting this object to 'active'. When 'active' is set, the system will validate the profile. Before a profile can be deleted or taken out of service (by setting this object to 'destroy' or 'outOfService'), it must be first unreferenced from all associated templates.

The table hwXdslPortIopCaptureInfoTable implement xDSL port IOP information capture. The index of this table is ifIndex.

The table hwXdslPortIopCaptureInfoTable implement xDSL port IOP information capture. The index of this entry is ifIndex.

Start or stop IOP information capture of xDSL port. Options: 1. start(1) - Start IOP information capture of xDSL port 2. stop(2) - Stop IOP information capture of xDSL port 3. invalid(-1) - Invalid value Enumeration: 'start': 1, 'stop': 2, 'invalid': -1.

Port IOP capture status Options: 1. noCapture(1) - Indicates that the capture is not performed 2. capturing(2) - Indicates that the capture is being performed 3. iop-generate(3) - Indicates that the IOP file is generated 4. captured(4) - Indicates that the capture is completed 5. invalid(-1) - Invalid value Enumeration: 'iop-generate': 3, 'noCapture': 1, 'capturing': 2, 'captured': 4, 'invalid': -1.

The table hwXdslDynamicInfoCollectTable implement xDSL port Dynamic information collect. The indexes of this table are hwFrameIndex and hwSlotIndex.

The table hwXdslDynamicInfoCollectTable implement xDSL port Dynamic information collect. The indexes of this entry are hwFrameIndex and hwSlotIndex.

Start Dynamic information collecting of xDSL port. Options: 1. start(1) - Indicates the collecting starts 2. invalid(-1) - Invalid value Enumeration: 'start': 1, 'invalid': -1.

Board Dynamic information collecting status. Options: 1. noCollect(1) - Indicates that collecting data is not performed 2. collecting(2) - Indicates that collecting data is being performed 3. collected(3) - Indicates that collecting data is complete Enumeration: 'noCollect': 1, 'collecting': 2, 'collected': 3.

Time at which collecting the optimization information is complete.

This object defines the operating port list of certain xDSL board. Each bit of this string specifies a port. If that bit has a value of '1', then that port is included in the set of ports; the port is not included if its bit has a value of '0'. For example, if 0xFE is set to this node, then port 0 to port 6 will start collection. If this node is not configed, collection will be started on all ports of the board.

This table provides one row for each ATUR. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The index of this table is ifIndex.

This table provides one row for each ATUR. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The index of this entry is ifIndex.

Start time of the current 15-minute performance statistics.

Start time of the current 1-day performance statistics.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during current 15 minutes. Each INMAINPEQ needs 4 bytes.

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. Each INMAIAT needs 4 bytes.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during current 1 day. Each INMAINPEQ needs 4 bytes.

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. Each INMAIAT needs 4 bytes.

This parameter is a count of the INMAINPEQi anomalies occurring on the line during the most recent previous 1-day period. Each INMAINPEQ needs 4 bytes.

This parameter is a count of the INMAME anomalies occurring on the line during the most recent previous 1-day period.

This parameter is a count of the INMAIATi anomalies occurring on the line during the most recent previous 1-day period. Each INMAIAT needs 4 bytes.

This parameter is a count of the INMAINPEQi anomalies occurring on the line ever before. Each INMAINPEQ needs 4 bytes.

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. Each INMAIAT needs 4 bytes.

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a far-end leftr defect present observed over the current 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 current 15 minutes accumulation period. The far-end counter is only defined in downstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the current 15 minutes accumulation period. The far-end value is only defined in downstream.

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a far-end leftr defect present observed over the current 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 current observed over the current 24 hours accumulation period. The far-end counter is only defined in downstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the current 24 hours accumulation period. The far-end value is only defined in downstream.

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

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the previous 24 hours accumulation period during this interval. The far-end counter is only defined in downstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the previous 24 hours accumulation period during this interval. The far-end value is only defined in downstream.

If retransmission is used in a given transmit direction, this parameter is a count of the seconds with a far-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. The far-end counter is only defined in downstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed ever before. The far-end value is only defined in downstream.

This table provides one row for each Atur performance data collection interval. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The indexes of this table are ifIndex and adslAturIntervalNumber.

This table provides one row for each Atur performance data collection interval. ADSL physical interfaces are those ifEntries where ifType is equal to adsl(94). The indexes of this entry are ifIndex and adslAturIntervalNumber.

Start time of the historical 15-minute performance statistics.

This parameter is a count of the INMAINPEQi anomalies occurring on the line at 15 minutes interval. Each INMAINPEQ needs 4 bytes.

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

This parameter is a count of the INMAIATi anomalies occurring on the line at 15 minutes interval. Each INMAIAT needs 4 bytes.

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

If retransmission is used in a given transmit direction, this parameter is a count of the number of error-free bits observed over the previous 15 minutes accumulation period during the interval. The far-end counter is only defined in downstream.

If retransmission is used in a given transmit direction, this parameter MINEFTR reports the minimum of the EFTR(Error-free throughput rate) observed over the 15 minutes accumulation period during the interval. The far-end value is only defined in downstream.

If ADSL act rate is lower than threshold, hwTrapType is 1. Otherwise, hwTrapType is 2. This trap message is generated when the ADSL port rate fails to meet the requirement.

ADSL act rate is change trap. This trap message is generated when the ADSL port rate changed.

XDSL dynamic collect trap. This trap message is generated when xDSL port Dynamic information collect.

ADSL delt trap. This trap message is generated when the ADSL port delt test finish.

ADSL port status change trap. This trap message is generated when the ADSL port status changed.

ADSL selt test start trap. This trap message is generated when the ADSL port selt test finish.

ADSL line profile change trap. This trap message is generated when the ADSL line profile changed.

ADSL alarm profile change trap. This trap message is generated when the ADSL alarm profile changed.

This trap message is generated when the ADSL port activation rate fails to reach the rate threshold.

This trap message is generated when the ADSL port activation rate succeeds in reaching the rate threshold.

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

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

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

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

This trap message is generated when the activation rate of the xDSL line is lower than the threshold.

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

This trap message is generated when the ADSL chipset recovers.

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

Indicates the threshold item.

The chipset id of the board.

RequestID.

ADSL selt test start result. Options: 1. normal - A message is returned indicating that the SELT is successful. 2. failed - A message is returned indicating that the SELT fails.

ADSL profile operate type. Options: 1.add(1) - Add an ADSL profile 2.modify(2) - Modify an ADSL profile 3.delete(3) - Delete an ADSL profile Enumeration: 'add': 1, 'modify': 2, 'delete': 3.

Indicate the threshold value of threshold item.

Indicate the current value of threshold item.