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PBN Networks Management Devices

PBN Networks Management Device Address

The OCM slot of the PBN device

The Device Page

The Device Parameter

The parameter status

The parameter string

The Write Parameter Value ID

The Toggle Parameter Value ID

The Toggle Parameter Value ID

CPON-100 Tamper alarm

CPON-100 Battery alarm

CPON-100 CATV alarm

CATV Service Control

Master Alarm Status

Tamper Status

CATV Service Status

Sensing Input

Packet Size

Multicast Storm Protection

Flow Control

Back Pressure Mode

Priority Buffer Reserve

Priority Scheme Select

802.1p Based priority

802.1q VLAN enable

Null VID Replacement

Source Address MAC Pause

Fast Age

CPON-100 SNMP MAC Address

CPON-100 Trap severity

CPON-100 Trap Message

CPON-100-100 VLAN1

CPON-100 VLAN2

CPON-100 VLAN3

Static MAC entry 1

Static MAC entry 2

Static MAC entry 3

Static MAC entry 4

Static MAC entry 5

Dynamic MAC Entry Count

Dynamic MAC Entry ID

Dynamic MAC entry data

Port1 Link Status

Port1 MID-X Status

Port1 Auto-Negotiation Status

Link Capability

Port1 Flow Control Capability

Port1 Far End Fault Status

Port1 Receive Low Priority Octet Counter

Port1 Receive High Priority Octet Counter

Port1 Undersize Packet Counter

Port1 Receive Jabbers Counter

Port1 CRC Error Counter

Port1 Receive Pause Packet Counter

Port1 Good Broadcast Packet counter

Port1 Receive Good Multicast Packet Counter

Port1 Receive Unicast Counter

Port1 Receive 64Octets Counter

Port1 Receive 65 to 127 Octets Counter

Port1 Receive 128 to 255 Octets Counter

Port1 Receive 256 to 511 Octets Counter

Port1 Receive 512 to 1023 Octets Counter

Port1 Receive 1024 to 1522 Octets Counter

Port1 Transmit Low Priority Good Octet Counter

Port1 Transmit High Priority Good Octet Counter

Port1 Pause Packet Counter

Port1 Transmit Good Broadcast Packet Counter

Port1 Transmit Good Multicast Packet Counter

Port1 Transmit Good Unicast Packet Counter

Port1 Transmit Total Collision Packet Counter for half-duplex only

Port1 Transmit Drop Packet Counter

Port1 Receive Drop Packet Counter

Port1 DiffServe Priority Control

Port1 802.1p Priority Class Enable

Port1 Port Based Priority

Port1 Priority Enable

Port1 Auto-Negotiation Enable

Port1 Force Full-duplex

Port1 Broadcast Storm Protection

Port1 Force Flow Control

Port1 Backpressure Enable

Port1 Transmit Enable

Port1 Receive Enable

Port1 Port Powerdown

Port1 MAC Loopback Test

Port1 PHY Loopback Test

Port1 Remote Loopback Test

Port1 Tag Insertion/Tag Removal

Port1 Port Membership

Port1 Ingress VLAN Filtering

Port1 Discard Non-PVID Packet

Port1 Default Tag

Port1 Force Speed

Port2 Link Status

Port2 MDI-X Status

Port2 Auto-Negotiation Status

Port2 Link Capability

Port2 Flow Control Capability

Port2 Far End Fault Status

Port2 Receive Low Priority Octet Counter

Port2 Receive High Priority Octet Counter

Port2 Undersize Packet Counter

Port2 Receive Jabbers Counter

Port2 CRC Error Counter

Port2 Receive Pause Packet Counter

Port2 Broadcast Good Packet Counter

Port2 Receive Multicast Good Packet Counter

Port2 Receive Unicast Counter

Port2 Receive 64 Octets Counter

Port2 Receive 65 to 127 Octets Counter

Port2 Receive 128 to 255 Octets Counter

Port2 Receive 256 to 511 Octets Counter

Port2 Receive 512 to 1023 Octets Counter

Port2 Receive 1024 to 1522 Octets Counter

Port2 Transmit Low Priority Packet Counter

Port2 Transmit High Priority Packet Counter

Port2 Pause Packet Counter

Port2 Transmit Broadcast Packet Counter

Port2 Transmit Multicast Packet Counter

Port2 Transmit Unicast Packet Counter

Port2 Transmit Total Collision Packet Counter

Port2 Transmit Dropped Packet Counter

Port2 Receive Dropped Packet Counter

Port2 DiffServe Priority Control

Port2 802.1p Priority Class Enable

Port2 802.1p Priority Class Enable

Port2 Priority Enable

Port2 Auto-Negotiation Enable

Port2 Force Full-duplex

Port2 Broadcast Storm Protection Enable

Port2 Force Flow Control

Port2 Back Pressure Enable

Port2 Transmit Enable

Port2 Receive Enable

Port2 Powerdown

Port2 MAC Loopback Test

Port2 PHY Loopback Test

Port2 Remote Loopback Test

Port2 Tag Insertion/Tag Removal

Port2 Port Membership

Port2 Ingress VLAN Filtering

Port2 Discard Non-PVID Packet

Port2 Default Tag

Port2 Force Speed

Uplink Link Status

Primary uplink Link Remote loopback test

Primary Uplink Transmit Low Priority Rate Control

Primary Uplink Receive Low Priority Rate Control

Primary Uplink Transmit Differential Priority Rate Control

OSLAM-8G Source MAC address =========================== 48bit Source address MAC address for pause control frame. NOTE: First bit of 2nd octet is as followed: This bit used to have all ports transmit the same or different source addresses in full-duplex Pause frames. 0 - All ports transmit the same Static Address (SA) 1 - Each port uses a different SA where bits 4:47 of the sourceMACAddress are the same, but bits 3:0 are the port number (Port 0 = 0, Port1 = 1, Port 2 = 2, etc.)

OSLAM-8G Scheduling Mode ========================= 1 - Use an 8,4,2,1 weighted fair queuing scheme 2 - Us a strict priority scheme

Maximum Frame Size allowed. =========================== The Ingress block discards all frames less than 64 bytes in size. It also discards all frames greater than a certain size (regardless of whether or not the frame is iEEE802.3ac tagged) as follows: 1 - Max size is 1522 for IEEE tagged frames, 1518 for untagged frames. 2 - Max size is 1632

OSLAM-8G Core Tag Type ====================== Core Tag Ether Type. This EtherType is added to frames that egress the switch as Double Tagged frames. It is also the EtherType expected during Ingress to determine if a frame is Tagged or not on ports configured in oslam8gPortEgressMode as follows: For Ingress: =========== oslam8gUseCoreTag= 1, oslam8gDoubleTag = 1, TagType = 0x8100 oslam8gUseCoreTag= 1, oslam8gDoubleTag = 2, TagType = 0x8100 oslam8gUseCoreTag= 2, oslam8gDoubleTag = 1, TagType = oslam8gCoreTagType oslam8gUseCoreTag= 2, oslam8gDoubleTag = 2, 1st TagType = oslam8gCoreTagType then 2nd TagType in the frame = 0x8100 For Egress: =========== Normal Add a Tag (standard IEEE rule) Added Tag Type = 0x8100 Always Add a Tag (Egress DoubleTag) Added Tag Type = oslam8gCoreTagType

OSLAM-8G Use Double Tag Data ============================ Used to determine if Double Tag data is removed from a Double Tag frame is used or ignored when making switching decisions on the frame. 1 - Ignore removed Tag data 2 - Use removed Tag data This OID have not effect if hte ports oslam8gPortDoubleTag is set to 1

OSLAM-8G Serial Number

OSLAM-8G SNMP MAC Address

OSLAM-8G Diagnostic Message

VLAN Table Unit Table Operation =============================== Support the following VTU operation. 0, 2 - No Operation 1 - Flush All Entries 3 - Load(1) or Purge(2) an Entry 4 - Get Next(3) 5,6 - Reserve 7 - Get/Clear Violation Data NOTE: (1) - An Entry is Loaded when the vtuValid is set to a one. Load is the only vtuOperation that uses the vtuDBNum field and it uses it as data to be loaded along with the desired vtuVID. (2) - An Entry is Purged when the vtuValid is cleared to a zero. (3) - A Get Next operation finds the next higher vtuVID curretnly in the database. The vtuVID value is used as the VID to start from. To find the lowest VID set the vtuVID field to ones. When the operation is done the vtuVID field contains the next higher VID currently active in the database. To find the next VID simply issue the Get Next opcode again. If the vtuVID field is returned set to a ones with the vtuValid cleared to zero, no higher VIDs were found. To Search for a particular VID, perform a Get Next operation using a vtuVID field with a value one less than the one being searched for.

VTU MAC Address Database Number =============================== On all vtuOperation except for Get Violation Data, this field is used to separate MAC address dtabases by a frames VID. If multiple address databases are not being used, theses bits must remain zero. If multiple addresss are not being used, theses bits must remain zero. If multiple address databases are being used, these bits are used to get the desired database number that is associated with VID value on Load operations (or used to read the currently assigned vtuDBNum on Get Next operations).

VTU Member Violation ================== Source Member Violation. On Get/Clear Violation Data vtuOperation, this value is returned set to a two(2) if the Violation being serviced is due to an 802.1Q Member Violation. A member Violation occurs when an 802.1Q enabled ingress port accesses the VTU with a VID that is cotnained in the VTU but whose Mebership list does not include this Ingress port. Only the first vtuFullViolation, vtuMemberViolation, vtuMissViolation is saved per port until cleared.

VTU Miss Violation ================== On Get/Clear Violation operation this value is set to a two(2) if the Violation being serviced is due to 802.1Q Miss Violation. A Miss Violation occurs when an 802.1Q enabled Ingress port accesses the VTU with a VID that is contained in the VTU. Only the first atuFullViolation, atuMemberViolation, atuMissViolation is saved per port until cleared.

VTU Entry Valid status. ======================= At the end of Get/Next operations 1 - If VID is all ones, it indicates the end of the VID list was reached with no new valid entries. 2 - Indicates the VID value below is valid. NOTE: On Load or Purge operations, this bit indicates the desired operation of a Load (when set to a one) or a Purge (when cleared to a zero).

VLAN Identifier =============== This VID is used in all the vtuOperation commands (except Get/Clear Violation Data) and it is the VID that is associated with the vtuData or the vtuVID that caused the VTU Violation. Theses indicate the VID number that is associated with the MemberTag in the vtuData, 802.1s PortState, Priority and its override.

VLAN table data Entry Format as follow: ====================== BYTE#: 5 4 3 2 1 0 Frame: [0:P10][P9:P8][P7:P6][P5:P4][P3:P2][P1:P0] Px: Port control Size: 4bits total Format: [PortState][PortMemberTag] PortState: The upper two bits of each ports VTU data is called 802.1s PortState. These bits are used to support 802.1s per VLAN spanning tree as follows: 00 - 802.1s Disabled. User non-VLAN Port states (in Port control portState) 01 - Blocking/Listening Port State for this port for frames with this VID 10 - Learning Port State for this port for frames with this VID 11 - Forwarding Port State for this port for frames with this VID NOTE: These 802.1s PortState bits take precedence over the ports portState in port control unless the ports portState is Disabled (which prevents all frames from flowing). MemberTag: Size: 2bits The lower two bits of each ports VTU data is called MemberTag. These bits are used to indicate which ports are members of the VLAN and if these VLANs frames should be tagged or untagged, or unmodified when exiting the port as follows: 00 - Port is a member of this VLAN and frames are to egress unmodified. 01 - Port is a member of this VLAN and frames are to egress Untagged. 10 - Port is a member of this VLAN and frames are to egress Tagged. 11 - Port is not a member of this VLAN

VID Priority ============ These bits are used to override the priority on any frames associated with this VID value, if the vtuVIDPRIOverride is set to one.

VID Priority Override ===================== 1 - No priority override. 2 - The vtuVIDPRI are used to override the priority on any frames associated with this VID as long as the ports portVTUPriOverride is set.

Address Translation Unit (ATU) Opcode: ====================================== 1 - Flush All Entries 2 - Flush all Non-Static Entries 3 - Load or Purge an Entry in a particular atuDBNum Database 4 - Get Next from a particular atuDBNum Database 5 - Flush all Entries in a particular atuDBNum Database 6 - Flush all Non-Static Entries in a particular atuDBNum Database 7 - Get/Clear Violation Data. 8 - No operation

ATU MAC Address Database Number (DBNum) ======================================= If multiple address databases are not being used theses bits must remain zero. If multiple address databases are being used theses are used to set the desired address database number that is being used on the Database supported commands (atuOperation 0x03, 0x04, 0x05 and 0x06). On Get/Clear Violation Data atuOperation these bits return the atuDBNum value associated with the ATU violation that was just serviced.

ATU Member Violation ================== On Get/Clear Violation operation this value is set to a two(2) if the Violation being serviced is due to a Source Address Look-up that resulted in a Hit but where the atuState and atuPortVec bits does not contain the frames Ingress port bit set to a two(2) (i.e. a station moved occurred). This violation can be masked on a per port basis by setting the ports ignoreWrongData bit. Only the first atuFullViolation, atuMemberViolation, atuMissViolation is saved per port until cleared.

ATU Miss Violation ================== On Get/CLear Violation operation this value is set to a two(2) if the Violation being serviced is due to a Source Address Look-up that resulted in a Miss on ports that are locked (i.e., CPU directed learning is enabled on the port). Only the first atuFullViolation, atuMemberViolation, atuMissViolation is saved per port until cleared.

ATU Full Violation ================== On Get/Clear Violation operation this value is set to a two(2) if the Violation being serviced is due to a Load operation or automatic learn that could not store the desired entry. This only occurs if all available locations for the desired address contain other MAC addresses that are loaded Static. Only the first atuFullViolation, atuMemberViolation, atuMissViolation is saved per port until cleared.

ATU Age Time ============ These bits determine the time that each ATU Entry remains valid in the database, since its last access as a source address, before being purged. The value in this register times 15 is the age time in seconds. For example: The default value of 0x14 is 20 decimal. 20x15 = 300 seconds or 5 minutes. If the atuAgeTime is 0xFF or 3825 seconds or almost 64 minutes. if the atuAgeTime is set to 0 the Aging function is disabled and all learned addresses will remain in the database forever.

TRUNK - Trunk Mappped Address ============================= 1 - The atuPortVec is the port vector assigned to this address. 2 - The data bits [7:4] of atuPortVec is the Trunk ID assigned to this address. atuPortVec bits [10:4] must be written as zero when this value is zet to a two(2).

Port Vector/Trunk ID ==================== If the atuTrunk is zero, theses bits are used as the input Port Vector for ATU Load operations and its the resulting Trunk ID for ATU load operations and its the resulting Trunk ID from ATU GetNext operations.

ATU Entry State =============== Used as the Entry State for ATU Load/Purge or Flush/Move operations and it is the resulting Entry State from ATU Get Next operations (GetNext is the only ATU operation supported in the devices). If theses equal to 0x0 then the atuOperation is a Purge or a Flush. If theses bits are not 0x0 then the atuOperation is a Load or a Move (a move atuOperation requires these bits to be 0x0F). On Get/Clear Violation Data atuOperation, theses bits return the Source Port ID(SPID) associated with the ATU violation that was just serviced. If SPID = 0xF the source of the violation was the CPUs register interface (i.e. the ATU was full during a CPU Load operation).

ATU MAC Address Entry: ====================== Byte pattern as follow: Opaque data Location: 5 4 3 2 1 0 MAC Byte Location : [5][4][3][2][1][0]

OSLAM-8G Port Force Flow Control Setting ======================================== 1 - Force No Flow Control 2 - Normal detection occurs 3 - Force Flow Control

OSLAM-8G Port Force Link ======================== 1 - Force to bring link down 2 - Normal link detection occurs 3 - Force to bring link up

OSLAM-8G Port Force Duplex Control ================================== 1 - Force Half-Duplex 2 - Normal duplex detection occurs. 3 - Force Full-Duplex

OSLAM-8G Port Force Speed ========================= 1 - 10Mbps 2 - 100Mbps 3 - 1000Mbps 4 - Speed is not forced. Normal speed detection occurs.

OSLAM-8G Ports Port State =========================== This OID is used to manage a port to determine what kind of frames, if any, are allowed to enter or leave a port for simple bridge loop detection or 802.1D Spanning Tree. This OID value can be change at any time without disrupting frames currently in transmit. 1 - Disabled. The port is disabled and it will not receive or transmit any frames. The QC returns any pre-allocated ingress queue buffers when the port is in this mode. 2 - Blocking/Listening. OSLAM-8G examines all frames without learning any SAs, and discards all frames. 3 - Learning. OSLAM-8G will examine all frames, learning all SA address (except those from MGMT frames), and still discard all but MGMT frames. It will allow MGMT frames only to exit the port. 4 - Forwarding. OSLAM-8G examines all frames, learning SAs from all good frames (except those from MGMT frames), and receives and transmits all frames as a normal switch.

OSLAM-8G Port Forward Unknown ============================= 1 - Unicast frames with unknown DAs will not egress out of this port. 2 - Normal operation occurs and unicast frames with unknown DA addresses are allowed to egress out of this port (assuming the VLAN settings allow the frame to egress this port too).

OSLAM-8G Port Default Forward ============================= 1 - Multicast frames with unknown DAs do not egress from this port. 2 - Normal switch operation occurs and multicast frames with unknown DA addresses are allowed to egress out this port (assuming the VLAN settings allow the frame to egress this port too).

OSLAM-8G Port Use IP for Priority ================================= Use IPv4 TOS and/or DiffServ fields and/or IPv6 Traffic Class fields, if present, for priority data. 1 - Ignore IPv4 and IPv6 priority fields. 2 - Use IPv4 fields if the frame is IPv4 and use IPv6 fields if the frame is IPv6 for priority data.

OSLAM-8G Port Use Core Tag ========================== Refer to oslam8gCoreTag 1 - Ingressing frames are considered tagged if the 16-bits following the frames source Address are 0x8100. 2 - Ingressing frames are considered tagged if the 16-bits following the frames source Address are equal to oslam8gCoreTagType NOTE: If a frame is Double Tagged and the first tag is removed (oslam8gPortDoubleTag) by matching the EtherType define by this bit, the resulting frame will be considered tagged only if the next 16 bits in the frame equal to 0x8100 (that is, the oslam8gCoreTagType is not used after the first tag is removed)

OSLAM-8G Port Double Tag ======================== Ingress Double Tag 2 - The ingressing frames are examined to see if they contain 802.3ac tag with the IEEE standard EtherType of 0x8100 or if they contain a tag with an EtherType defined in oslam8gCoreTag. The oslam8gCoreTag will be used if this ports oslam8gPortUseCoreTag is used. If the frames do contain the expected tag, the tag is removed (and the CRC is recomputed). Essentially, untagged frames remain untagged, single tagged frames become untagged and double tagged frames become single tagged. These now single tagged frames will be considered tagged only if its EtherType value is 0x8100 no matter what the EtherType value was found on the removed tag. No padding is performed so a tagged frame must be at least 68bytes in size or it will be discarded. 1 - Tagged frames are not modified when received. The Tag data that is removed from the frame can be ignored (i.e., the frame is treated as if the removed tag never existed) or the removed Tag data can be used for switching and priority decisions (i.e., the removed Tags VID and PRI bits are internally assigned to the frame). The action that is taken is controlled by the oslam8gUseDoubleTagData

OSLAM-8G Port Egress Rate Limit ================================ Modify this ports effective transmission rate. This support 62kbps to 256Mbps. Formula to limit the Egress data rate: EgressRate = 8 bits/ (32ns * Egress Rate bits/sec) Where, => Egress Rate is in bits per second. For example: ============ For 256Kbps rate the value of this oslam8gPortEgressRate should be: = 8/(32ns * 256Kbps) = 976 The value to be programmed for this OID is 976. 976 is actually equated to 256.14Kbps

OSLAM-8G Port Ingress Limit Mode ================================ Determine what kinds of frames are limited and counted against Ingress limiting. 1 - Limit and count all frames. 2 - Limit and count Broadcast, Multicast and flooded unicast frames. 3 - Limit and count Broadcast and Multicast frames only. 4 - Limit and count Broadcast frames only. NOTE: If a frame is not limited by the above setting, its size is not counted against the limit for the other frames.

OSLAM-8G Port Priority 3 Rate Control ===================================== Priority 3 frames are discarded after the ingress rate selected below is reached or exceeded: 1 - Use the same rate as oslam8gPortIngressPri2Rate 2 - Use twice the rate as oslam8gPortIngressPri2Rate (but no faster than the ports speed)

OSLAM-8G Port Priority 2 Rate Control ===================================== Priority 2 frames are discarded after the ingress rate selected below is reached or exceeded: 1 - Use the same rate as oslam8gPortIngressPri1Rate 2 - Use twice the rate as oslam8gPortIngressPri1Rate (but no faster than the ports speed)

OSLAM-8G Port Priority 1 Rate Control ===================================== Priority 1 frames are discarded after the ingress rate selected below is reached or exceeded: 1 - Use the same rate as oslam8gPortIngressPri0Rate 2 - Use twice the rate as oslam8gPortIngressPri0Rate (but no faster than the ports speed)

OSLAM-8G Port Priority 0 Rate Control ===================================== Priority 1 frames are discarded after the ingress rate selected below is reached or exceeded: OSLAM-8G use the following formula to calculate rate limiting: Pri0Rate = 8 bits/ (32ns * Ingress Rate bits/sec) Where, => Ingress Rate is in bits per second. For example: ============ For 128Kbps rate the value of this oslam8gPortEgressRate should be: = 8/(32ns * 128Kbps) = 1953

OSLAM-8G Port Use Tag ===================== Use IEEE Tags. Use IEEE 802.1p Traffic Class field for priority data if the frame is an IEEE 802.3ac tagged frame. 1 - Ignore IEEE 802.1p tag fields even it the frame is tagged. In this mode, tagged frames that enter this port and egress the OSLAM-8G tagged are re-tagged with this ports default priority bits, if no other priorities are determined fro the frame (i.e., the frames IP priority and/or other priority overrides). This works as a Force Default Priority function on tagged frames. 2 - Use IEEE 802.1p tag Traffic Class for priority data if the frame is tagged.

OSLAM-8G Ports Port Membership =============================== Port based VLAN Table. The bits in this value are used to restrict which output ports this input port can send frames to. This value are used for all frames even if 802.1Q is enabled on this port or if ProtectedPort is enabled on this port. These bits restrict where a port can send frames (unless a oslam8gPortVLANTunnel frame is being received. => To send frames to Port 0, bit 0 of this register must be a one. => To send frames to Port 1, bit 1 of this register must be a one. etc.

OSLAM-8G Port Default Priority ============================== Used as the default ingress priority to use when no other priority information is available (neither is the frame IEEE Tagged, nor is it an IPv4 nor an IPv6 frame - or the frame is a priority type that is currently disabled (see oslam8gPortUseIPPriority and oslam8gPortUseTag) and no other priority overrides are active on this frame. The default priority are remapped by the oslam8gPortPriRemap prior being used.

OSLAM-8G Port 802.1Q Mode ========================= IEEE 802.1Q Mode for this port. These bits determine if 802.1Q based VLANs are used along with port based VLANs for this Ingress port. If also determines the action to be taken if an 802.1Q VLAN Violation is detected. 1 - 802.1Q disabled. Use Port Based VLANs only. The oslam8gPortMembership and oslam8gPortDefVID assigned to the frame during ingress determine which Egress ports this Ingress is allowed to switch frames to for all frames. 2 - Fallback. Enable 802.1Q for this Ingress port. Do not discard Ingress Membership violations and use the oslam8gPortMembership if the frames VID is not contained in the VTU. 3 - Check. Enabled 802.1Q for this Ingress port. Do not discard Ingress Membership violation but discard the frame if its VID is not contained in the VTU. 4 - Secure. Enabled 802.1Q for this Ingress port. Do not discard Ingress Membership violations and discard frames whose VID is not contained in the VTU.

OSLAM-8G Port Tagged/Untagged Discard Mode ========================================== 1 - No discard of Frames 2 - Only Discard Untagged Frames. All non-MGMT frames that are processed as untagged are discarded as they entering this switch port. This test is performed after Ingress Double Tag removal (if enabled). 3 - Only Discard Tagged Frames. All non-MGMT frames that are processed as tagged are discarded as they entering this switch port. This test is performed after Ingress Double Tag removal (if enabled). Priority only tagged frames (with a VID of 0x00) are considered tagged. 4 - Both Discard Tagged and Untagged frames.

OSLAM-8G Port Default VLAN Identifier ===================================== When 802.1Q is enabled on this port this value is used as the IEEE Tagged VID added to untagged or priority tagged frames during egress that ingressed from this port. It is also used as a tagged frames VID if the frames VID was 0 (i.e., it is a priority tagged frame) or if the ports oslam8gPortForceDefVID is set to one. When 802.1Q is disabled on this port, this value field is assigned to all frames entering the port (if are tagged or untagged). This assignment is used internal to the switch, so only Port Based VLANs can be supported.

OSLAM-8G Port VLAN Tunnel ========================= 1 - The port based VLANs defined in oslam8gPortPortMembership, 802.1Q VLANs defined in the oslam8g-802dot1QVLAN (if 802.1Q is enabled) and oslam8gTrunkMask are enforced for ALL frames. 2 - The port based oslam8gPortPortMembership, 802.1Q VLAN membership masking and oslam8gTrunkMask is bypassed for any frame entering this port with a DA that is currently static in the oslam8g-atu. This applies to unicast as well as multicast frames.

OSLAM-8G Port VTU Priority Override =================================== 1 - Normal frame priority processing occurs. 2 - The VTU priority overrides can occur on this port. A VTU priority override occurs when the determined VID of a frame resuls in a VID whose oslam8gVTUVIDPRIOverride in the VTU VLAN database is set. When this occurs the VIDPRI value assigned to the frames VID is used to overrite the frames previously determined priority. If the frame egresses tagged the priority in the frame will be this new VIDPRI value. When used the upper two bits of the VIDPRI priority determine the Egress Queue the frame is switched into. THE VTU Priority Override has higher priority than the ports Default Priority and the frames IEEE and/or IP priorities. The priority determined by the frames VID can be overridden, however, by the frames SA and/or DA prority Overrides.

OSLAM-8G Port Force Default VID =============================== For to use Default VID. When 802.1Q is enabled on this port and 1 - All IEEE 802.3ac Tagged frames with a non-zero VID used the frames VID unmodified. 2 - All ingress frames with IEEE 802.3ac Tags have their VID ignored and the ports oslam8gPortDefaultVID is used and replaced into the frame instead. When 802.1Q is disabled on this port, this bit has no effect.

OSLAM-8G Port Egress Mode ========================= The first three Egrress Modes are used as the default Egress mode for frames whose VID is not valid in the oslam8g-802dot1QVLAN or if 802.1Q is disabled on the port. The fourth Egress Mode is applied to all frames all the time (if selected) even if 802.1Q is enabled on the port. 1 - Default to Normal mode. Frames are transmitted unmodified. 2 - Default to Transmit all frames Untagged. Remove the tag from any tagged frame. 3 - Default to Transmit all frames Tagged. Add a tag to any untagged frame. 4 - Always add a Tag (or Egress Double Tag). This setting is not a default setting. It ignores the MemberTag in vtuData of oslam8g-802dot1QVLAN for this port. The EtherType used for these inserted tags come from oslam8gCoreTag.

OSLAM-8G Port IEEE Priority Remapping ==================================== Byte#: 3 2 1 0 Format: [TagRemap7:TagRemap6][TagRemap5:TagRemap4][TagRemap3:TagRemap2][TagRemap1:TagRemap0] TagRemap0: Tag Remap 0. All IEEE tagged frames with a priority of 0 get this value as the frames new priority inside the switch. If a tagged frame egresses the switch tagged, this new priority is written to the frames tag. TagRemap1: Tag Remap 1. All IEEE tagged frames with a priority of 1 get this value as the frames new priority inside the switch. If a tagged frame egresses the switch tagged, this new priority is written to the frames tag. TagRemapX: Tag Remap X. All IEEE tagged frames with a priority of X get this value as the frames new priority inside the switch. If a tagged frame egresses the switch tagged, this new priority is written to the frames tag.

Link Status: ============ This indicates the link status of the selected port 1 - Link is down 2 - Link is Up

Duplex Mode: ============ Valid if link status is up. 1 - Half-Duplex 2 - Full-Duplex

Speed Mode: =========== Valid if link status is up. 1 - 10MBps 2 - 100MBps 3 - 1000MBps 4 - Reserved for future used

Histogram Counters Mode: ======================== The Histogram mode control how the Histogram counters work as follows. 1 - Count received frames only 2 - Count transmitted frames only 3 - Count receive and tranmitted frames

Target Node Address: ==================== FPCM is a broadcast device. 10 digits decimal address required to access the target optical node. Value of 4294967295 represent a broadcast address i.e. message will be send to all connected node. This value is the serial number of the ODN4P-ABC.

AB Switching Mode: ================== The mode of operation for ODN4P-AB. Available operation mode are: - AUTOMATIC - MANUAL

Channel Select: =============== The channel to be selected by the AB redundancy switch. Upon changing the channel, AB operation mode at the target device will change to MANUAL mode automatically.

Switch Hysteresis: ================== Primary Optical recovery level.

Primary switch-over time: ========================= The number of second wait required before change of state

Secondary switch-over time: =========================== The number of second wait required before change of state

Attenuator 1: ============= Attenuation used for ingress control. Unit is in 1dB step. Acceptable value range: 2-40dB

Attenuator 2: ============= Attenuation used for ingress control. Unit is in 1dB step. Acceptable value range: 2-40dB

Attenuator 3: ============= Attenuation used for ingress control. Unit is in 1dB step. Acceptable value range: 2-40dB

Attenuator 4: ============= Attenuation used for ingress control. Unit is in 1dB step. Acceptable value range: 2-40dB

Remote node FSK home channel: ============================= Each network may use different default FSK channel. This is the default FSK channel to be managed by operator. Optical node always tune to home channel prior to agility.

FSK Operating mode ================== Force FSK to operate in either FIX or AGILE mode. FIX - FSK receiver always try to lock to the known FSK frequency AGILE - Always search for an FSK channel that is capable of decoding data

ODN4P LOOP TEST =============== Acceptable value is 0-255 or 8-bit number. Value between between 1..255 will be display on the connected RPQRM of the selected channel if this OID has been iniated. Set value to 0xFB will clear loopback test and normal data will then be seen in the RPQRM. Operator should only use value between 0x70 to 0x7F for testing Other values are reserved for NETCRAFT

Node Access Control Data Length: ================================ This usually used by remote management software (NMS3) Operator should ignore or do not change this OID value.

Node Access Control Data: ========================= This usually used by remote management software (NMS3) Operator should ignore or do not change this OID value.

Node Access Control Command: ============================ This usually used by remote management software (NMS3) Operator should ignore or do not change this OID value.

FSK Channel modulated by FPCM: ============================== Acceptable FSK channel range 0-100. FSK modulation range 80-90MHz (Channel 0-100 respectively)

FPCM RF level ============= RF level setting in 1dBmV scale. Current supported value is 25-45dBmV

Product model name

Product version number

Product build date

VAC input type. e.g. 220V

+5V supply voltage level. Unit is in Volt e.g. 4.92V

+12V supply voltage level. Unit is in Volt e.g. 12.00V

+24V supply voltage level. Unit is in Volt e.g. 24.10V

Optical input power level. Unit is in dBm e.g. -2.05dBm

Optical input power level. Unit is in dBm e.g. -2.05dBm

Total RF output power level. Unit is in dBmV e.g. 41.23dBmV total or 25.00dBmV/Ch@42Ch.

Module internal temperature. Unit is in Degree Celsius e.g. 29.25C

Device lid open/close status

EPON-ONU installed status.

MOCA installed status.

PLC installed status.

Status LED

Gain control LED (AGC/MGC) status. ON - AGC mode OFF - MGC mode

Optical input high led indicator ON - Optical input is too high.

Optical input LOW led indicator ON - Optical input is too low.

+5V Supply MIN voltage alarm level

+5V Supply MAX voltage alarm level

+12V Supply MIN voltage alarm level

+12V Supply MAX voltage alarm level

+24V Supply MIN voltage alarm level

+24V Supply MAX voltage alarm level

Optical Input Power MIN alarm level

Optical Input Power MAX alarm level

Optical Output Power MIN alarm level

Optical Output Power MAX alarm level

Temperature MIN alarm level

Temperature MAX alarm level

Gain Control MIN Level

Gain Control MAX Level

AGC lock when the controlled signal is within range. AGC unlock when agc cannot control the signal or signal is out of range for AGC to operate.

RF gain control setting. 1dB control step. Control range to be adviced.

Indicates if this trap entry is enabled or not.

Primary Community String to be used by agent for SNMP GET/SET for mauTrapPrimaryReceiverIPAddress

Secondary Community String to be used by agent for SNMP GET/SET for mauTrapSecondaryReceiverIPAddress

The primary Trap Receiver station IP address

The secondary Trap Receiver station IP address

Displays the tag name of the device in human-readable format as set by user.

Displays the name of the device model number in human-readable format as set from the factory.

Displays the manufacturing date in human-readable format as set from the factory.

Displays the serial number in human-readable format as set from the factory.

Displays the software revision of the device in human-readable format.

Displays the engineering revision in human-readable format as set from the factory.

Returns the unit temperature.

Returns measured laser bias current.

Returns the measured laser temperature.

Returns the input RF level.

Returns the measured composite RF level.

Returns the current of thermoelectric cooler inside the laser asssembly.

Manual mode RF attenuator setpoint.

Optical modulation index is implemented for CW or Video AGC modes as RF attenuator setpoint.

Returns the AGC mode.

Fiber dispersion compensation On/Off control.

Fiber dispersion gain compensation.

Fiber dispersion phase compensation.

Fiber dispersion slope compensation.

returns the active laser On/Off status.

Returns the status of the front panel keyswitch.

Remote laser On/Off control.

This object reports the cause of the last reset.

This object is used to reset the transmitter module by writing a 1 to it. Other values written to the object have no effect. Reading the object returns a 1 and has no effect on the module.

Returns the measured value of the +5V supply.

Returns the measured value of the +12V supply.

Returns the measured value of the +24V supply.

Returns the measured value of the -5V supply.

Returns the measured value of the -12V supply.

Indicates the unit status alarm enable. This value is bit encoded therefore it is capable of indicating multiple alarm enable conditions. The bits are defined as follows: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System | Laser | Laser | Laser | Laser | Input | Input | | Temp | Temp |Current|Current| Temp | Temp | RF | RF | | High | Low | High | Low | High | Low | Level | Level | | | | | | | | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |Optical|Optical| TEC | AGC |Key in |Remote | | | | Power | Power |Current| Unlock| Off | Off | | | | Out | Out | High | |Position Mode | | | | High | Low | | | | Set | | | +-------+-------+-------+-------+-------+-------+-------+-------+

Returns a bit mapped status word where each bit set (as defined below) indicates a specific active alarm: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System | Laser | Laser | Laser | Laser | Input | Input | | Temp | Temp |Current|Current| Temp | Temp | RF | RF | | High | Low | High | Low | High | Low | Level | Level | | | | | | | | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |Optical|Optical| TEC | AGC |Key in |Remote | | | | Power | Power |Current| Unlock| Off | Off | | | | Out | Out | High | |Position Mode | | | | | | | | | Set | | | +-------+-------+-------+-------+-------+-------+-------+-------+

Returns a bit mapped status word where each bit set (as defined below) indicates a specific active warning: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System | Laser | Laser | Laser | Laser | Input | Input | | Temp | Temp |Current|Current| Temp | Temp | RF | RF | | High | Low | High | Low | High | Low | Level | Level | | | | | | | | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |Optical|Optical| TEC | AGC |Key in |Remote | | | | Power | Power |Current| Unlock| Off | Off | | | | Out | Out | High | |Position Mode | | | | High | Low | | | | Set | | | +-------+-------+-------+-------+-------+-------+-------+-------+

Returns a bit mapped status word where each bit set (as defined below) indicates a an alarm had occurred since the last power up or clear: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System | Laser | Laser | Laser | Laser | Input | Input | | Temp | Temp |Current|Current| Temp | Temp | RF | RF | | High | Low | High | Low | High | Low | Level | Level | | | | | | | | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |Optical|Optical| TEC | AGC |Key in |Remote | | | | Power | Power |Current| Unlock| Off | Off | | | | Out | Out | High | |Position Mode | | | | High | Low | | | | Set | | | +-------+-------+-------+-------+-------+-------+-------+-------+ Clear status history by writing a value of 0.

Indicates the miscellaneous status alarm enable. This value is bit encoded therefore it is capable of indicating multiple alarm enable conditions. The bits are defined as follows: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ | 2 GHz | 2 GHz | 6 GHz | 6 GHz |System |System |System |System | | SBS | SBS | SBS | SBS | +5V | +5V | +12V | +12V | | Power | Power | Power | Power | Power | Power | Power | Power | | High | Low | High | Low | High | Low | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System |System |System |System |System | Comm | | | +24V | +24V | -5V | -5V | -12V | -12V |Failure| | | Power | Power | Power | Power | Power | Power | | | | High | Low | High | Low | High | Low | | | +-------+-------+-------+-------+-------+-------+-------+-------+ 16 17 18 19 20 21 22 23 +-------+-------+-------+-------+-------+-------+-------+-------+ | Power | Power |Cooling|Cooling| | | | | | Supply| Supply| Fan | Fan | | | | | | A | B | A | B | | | | | |Failure|Failure|Failure|Failure| | | | | +-------+-------+-------+-------+-------+-------+-------+-------+

Returns a bit mapped status word where each bit set (as defined below) indicates a specific active alarm: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ | 2 GHz | 2 GHz | 6 GHz | 6 GHz |System |System |System |System | | SBS | SBS | SBS | SBS | +5V | +5V | +12V | +12V | | Power | Power | Power | Power | Power | Power | Power | Power | | High | Low | High | Low | High | Low | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System |System |System |System |System | Comm |Power | | +24V | +24V | -5V | -5V | -12V | -12V |Failure|Supply | | Power | Power | Power | Power | Power | Power | |Failure| | High | Low | High | Low | High | Low | | | +-------+-------+-------+-------+-------+-------+-------+-------+ 16 17 18 19 20 21 22 23 +-------+-------+-------+-------+-------+-------+-------+-------+ | Power | Power |Cooling|Cooling| | | | | | Supply| Supply| Fan | Fan | | | | | | A | B | A | B | | | | | |Failure|Failure|Failure|Failure| | | | | +-------+-------+-------+-------+-------+-------+-------+-------+

Returns a bit mapped status word where each bit set (as defined below) indicates a specific active warning: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ | 2 GHz | 2 GHz | 6 GHz | 6 GHz |System |System |System |System | | SBS | SBS | SBS | SBS | +5V | +5V | +12V | +12V | | Power | Power | Power | Power | Power | Power | Power | Power | | High | Low | High | Low | High | Low | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System |System |System |System |System | Comm |Power | | +24V | +24V | -5V | -5V | -12V | -12V |Failure|Supply | | Power | Power | Power | Power | Power | Power | |Failure| | High | Low | High | Low | High | Low | | | +-------+-------+-------+-------+-------+-------+-------+-------+ 16 17 18 19 20 21 22 23 +-------+-------+-------+-------+-------+-------+-------+-------+ | Power | Power |Cooling|Cooling| | | | | | Supply| Supply| Fan | Fan | | | | | | A | B | A | B | | | | | |Failure|Failure|Failure|Failure| | | | | +-------+-------+-------+-------+-------+-------+-------+-------+

Returns a bit mapped status word where each bit set (as defined below) indicates a an alarm had occurred since the last power up or clear: 0 1 2 3 4 5 6 7 +-------+-------+-------+-------+-------+-------+-------+-------+ | 2 GHz | 2 GHz | 6 GHz | 6 GHz |System |System |System |System | | SBS | SBS | SBS | SBS | +5V | +5V | +12V | +12V | | Power | Power | Power | Power | Power | Power | Power | Power | | High | Low | High | Low | High | Low | High | Low | +-------+-------+-------+-------+-------+-------+-------+-------+ 8 9 10 11 12 13 14 15 +-------+-------+-------+-------+-------+-------+-------+-------+ |System |System |System |System |System |System | Comm |Power | | +24V | +24V | -5V | -5V | -12V | -12V |Failure|Supply | | Power | Power | Power | Power | Power | Power | |Failure| | High | Low | High | Low | High | Low | | | +-------+-------+-------+-------+-------+-------+-------+-------+ 16 17 18 19 20 21 22 23 +-------+-------+-------+-------+-------+-------+-------+-------+ | Power | Power |Cooling|Cooling| | | | | | Supply| Supply| Fan | Fan | | | | | | A | B | A | B | | | | | |Failure|Failure|Failure|Failure| | | | | +-------+-------+-------+-------+-------+-------+-------+-------+ Clear status history by writing a value of 0.

Returns a bit mapped status word where each bit set (as defined below) indicates a specific LED state: 0 1 2 3 4 5 +-------+-------+-------+-------+-------+-------+ | Laser | Laser |Status |Status |Status |LaserOn| | On | Off | Okay | Major | Minor | Rear | | | | | Alarm | Alarm | Panel | | Green | Red | Green | Red | Red | Green | +-------+-------+-------+-------+-------+-------+

No alarms are present.

The system temperature has exceeded its normal operating value.

The system temperature has exceeded its normal operating value.

The laser current has exceeded its normal operating value.

The laser current has exceeded its normal operating value.

The laser temperature has exceeded its normal operating value.

The laser temperature has exceeded its normal operating value.

The input RF level has exceeded its normal operating value.

The input RF level has exceeded its normal operating value.

The optical power output has exceeded its normal operating value.

The optical power output has exceeded its normal operating value.

The thermoelectric cooler current has exceeded its normal operating value.

The RF attenuator automatic gain control (AGC) is outside its normal operating range.

The key switch is in the OFF position.

The remote laser control is commanded to be in OFF mode.

The 2GHz SBS output power has exceeded its normal operating value.

The 2GHz SBS output power has exceeded its normal operating value.

The 6GHz SBS output power has exceeded its normal operating value.

The 6GHz SBS output power has exceeded its normal operating value.

The system +5V power supply has exceeded its normal operating value.

The system +5V power supply has exceeded its normal operating value.

The system +12V power supply has exceeded its normal operating value.

The system +12V power supply has exceeded its normal operating value.

The system +24V power supply has exceeded its normal operating value.

The system +24V power supply has exceeded its normal operating value.

The system -5V power supply has exceeded its normal operating value.

The system -5V power supply has exceeded its normal operating value.

The system -12V power supply has exceeded its normal operating value.

The system -12V power supply has exceeded its normal operating value.

A failure was detected with the internal network communication interface.

A failure was detected with power supply module A.

A failure was detected with power supply module B.

A failure was detected with cooling fan A.

A failure was detected with cooling fan B.

Returns the installed power supply type. single5V(1) - Single AC/DC power supply with rated output of 5V at 100W. dualRedundant5V(2) - Dual, redundant AC/DC power supplies with rated output of 5V at 100W each. single5-12-24V(3) - Single AC/DC power supply with rated outputs of 5V, +/-12V and 24V at 100W total. dualRedundant5-12-24V(4) - Dual, redundant AC/DC power supplies with rated outputs of 5V, +/-12V and 24V at 100W total.

Returns the power supply regulator temperature.

Returns the operating status of power supply A.

Returns the operating status of power supply B.

Returns the operating status of chassis cooling fan A.

Returns the operating status of chassis cooling fan B.

Returns the number of elapsed seconds since the last time the unit restarted.

No alarms are present.

A failure was detected with power supply module A.

A failure was detected with power supply module B.

A failure was detected with chassis cooling fan A.

A failure was detected with chassis cooling fan B.