SNMP MIB Search

This object should be used to generate unique indices when creating
rows in the cwrRadioHistoryGroup, cwrRadioTimelineGroup, and the
cwrRadioSnapshotGroup. Every GET request will generate a new index.
The index will not be unique across power cycles of the router.

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).
Each of these entries are indexed by the value of ifIndex as defined
in RFC2233.

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).
Each of these entries are indexed by the value of ifIndex as defined
in RFC2233.

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).
Each of these entries are indexed by the value of ifIndex as defined
in RFC2233.

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).
Each of these entries are indexed by the value of ifIndex as defined
in RFC2233.

This represents one entry in the cwrRfTable. This table is largely
a read only table which provides details on the state of radio
frequency resources available on the system.
Physically each RF resource may be realized by one antenna
and its associated control hardware. A single antenna and its
associated electronics may act as more than 1 RF resource.
When an RF resource acts as both a transmit and receive resource, the
transmit and receive frequency ranges may overlap.
It is indexed by the ifIndex and cwrRfIndex.

This represents one entry in the cwrIntFreqTable.
This table is largely a read only table which provides details
on the state of the intermediate frequency subsystem available on the
wireless radio.

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).
Each of these entries are indexed by the value of ifIndex as defined
in RFC2233.

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).
Each of these entries are indexed by the value of ifIndex as defined
in RFC2233.

This represents one entry in the cwr24HrMetricsTable indexed by ifIndex
and cwr24HrMetricsIndex.
The first entry in the table (cwr24HrMetricsIndex = 1) represents the
chronologically oldest data available.

This represents one entry in the cwr1HrMetricsTable indexed by ifIndex
and cwr1HrMetricsIndex.
The first entry in the table (cwr1HrMetricsIndex = 1) represents the
chronologically oldest data available.

This represents one entry in the cwr1MinMetricsTable indexed by ifIndex
and cwr1MinMetricsIndex.
The first entry in the table (cwr1MinMetricsIndex = 1) represents the
chronologically oldest data available.

This represents one entry in the cwr1SecMetricsTable indexed by ifIndex
and cwr1SecMetricsIndex.
The first entry in the table (cwr1SecIndex = 1) represents the
chronologically oldest data available.

This represents one entry in the cwrHistogramTable.
It is indexed by the ifIndex, cwrHistIndex.

This represents one entry in the cwrHistSummaryTable.
It is indexed by the ifIndex and cwrHistIndex.

This represents one entry in the cwrHistDataTable. It is indexed by the
ifIndex and cwrHistIndex and cwrHistBinIndex.

This represents one entry in the cwrThresholdTable.

This represents one entry in the cwrTlCtrlTable.
It is indexed by the ifIndex, cwrTlClass, cwrRfResourceId,
cwrTlDspNum.

This represents one entry in the cwrTlSummaryTable.
It is indexed by the ifIndex and cwrTlIndex.

This represents one entry in the cwrTlDataTable. It is indexed by
ifIndex, cwrTlIndex, and cwrTlValueIndex.

This represents one entry in the cwrSnapshotCtrlTable
It is indexed by the ifIndex and cwrSnapshotDspNum.

This represents one entry in the cwrSnapSummaryTable. It is indexed
by the ifIndex and cwrSnapDspNum.

This represents one entry in the cwrSnapDataTable. It is indexed by the
ifIndex and cwrSnapValueIndex.
The values in this table represent real numbers or complex numbers.
If they are real numbers then cwrRealPart contains the data and
cwrImaginaryPart is zero.

This represents one entry in the cwrAntennaTable. This table provides
details on the antennas available for use on the local system. It is
indexed by cwrAntennaIndex.

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).

There exists one such entry for every interface in the ifTable which
has an ifType of propWirelessP2P(157).

This represents one entry in this table.

This object specifies whether the radio should act as the
master or as the slave. The slave radio tracks the master's frequency.

This object specifies the whether self test should be
executed and if so whether to do it every time the radio link is
started. Any changes made to this object will reflected the next time
the radio link is started.
off(1) - Self test never performed.
once(2) - Self test will be performed the next time the radio link is
started.
always(3) - Every time the radio link is started.

This object specifies whether the Baseline Privacy feature is
available for use on this radio interface. If true then privacy is
supported.

This object specifies the index into the cwrRfTable identifying the
antenna used for transmission. This index will be 0 if the associated
transmit antenna is not present.

This object specifies the index of the first receive antenna identified
by the cwrRfTable. This index will be 0 if the associated receive
antenna is not present.

This object specifies the index of the second receive antenna in the
cwrRfTable. This index will be 0 if the associated receive
antenna is not present.

When this object is set to true(1), the wireless radio uses a
10MHz external reference clock.

For normal operation this should be set to false(2). If it set
true(1), then the radio link is placed in antenna alignment mode.
In this mode control signals are sent to the RF
resource which enables the operator to monitor the signal
received strength at the RF resource. This is mainly used
for antenna steering i.e. positioning the antenna for the best
possible signal reception.
If set to true(1), the radio link's response to rapid changes
in signal strength may potentially be affected.

This object specifies the number of antennas to be used to receive
the wireless transmissions.

This object specifies the bandwidth to use.  Given bandwidth, the
actual throughput of the radio link is determined by the
cwrThroughput setting.

This represents an throughput expected of the identified radio link.
There are 3 possible settings. The settings provide a tradeoff between
bandwidth and the reliability of the radio link. The settings are:
high(1): For a high throughput. The radio hardware will be
configured such that it, favors throughput over error
correction. It  may not be able to correct all received errors.
medium(2): This is a balance between high and low.
low(3): The radio hardware is configured such that it trades off
throughput for latency and error correction. It tries its very
best to correct errors it detects.

This object represents the portion of the frequency spectrum in which
the radio PHY will operate.
bandUNII(1) - The U-NII (Unlicensed National Information Infrastructure)
band represents the frequency range 5725.25 to
5823.75 MHz.
bandMMDS(2) - The MMDS (Multichannel Multipoint Distribution Service)
band represents the frequency range 2150.75 to
2688.25 MHz.
bandOther(3)- For all other frequenciy ranges.

This object represents the center frequency that will be used to
transmit data over the radio PHY. The specified transmit frequency must
match the operating band and the capability of the RF resource connected
to the radio.

This object represents the center frequency that will be used to
receive transmissions over the radio PHY. The specified receive
frequency must match the operating band and the capability of the
RF resource connected to the radio. The transmit frequency at
the local end must be identical to the receive frequency at the remote
end for a wireless link	to be established.

This object represents the power that the antenna will transmit.
The minimum average transmit power for the U-NII or MMDS band is
0.01 microwatts	(-80 dBm). Maximum average transmit power:
For the MMDS band is 2 Watts i.e. (+33dBm).
For the U-NII band is 100 milliwatts i.e. (+20dBm).
The power is specified in dBm.

This object represents the measured loss in signal power in dB that is
imposed by the cable connecting the radio to the antenna head.
This value enables the hardware to compensate for the cable loss by
adjusting the gain appropriately.
A value of 0 represents no degradation in signal due to the cable.
This cable loss applies to the transmit antenna identified by
cwrTxRfIndex.

This represents the current state of a radio Link.
notOperational(1): The link is not operational.
selftest(2) : Power on self test in progress
download(3): Image download is in progress.
txOnly(4): The radio link will switch to this state if
the radio link is configured for transmit only.
acquiring(5): Attempting to sync up with the far end transmitter.
receiveUp(6):  The receive side of the radio link has successfully
sync'ed up with remote end.
transmitUp(7): Transmit side of the radio link is up and running.
linkOperational(8): The radio link is ready for duplex communication.

This object represents the measured loss in signal power in dB that is
imposed by the cable connecting the radio to the antenna head.
This value enables the hardware to compensate for the cable loss by
adjusting the gain appropriately.
A value of 0 represents no degradation in signal due to the cable.
This cable loss applies to the receive antenna identified by
cwrRxRf2Index.

This object defines the time duration of the data burst sent over the
air.  The burst size is dependant on the capability of the ODU which
is represented by the cwrBurstSizeGroup variable in the cwrRfTable.
The user must set this object based on the value of cwrBurstSizeGroup in
the cwrRfTable.
The approximate time duration for each of the burst sizes are:
small(1):  50 microseconds
medium(2): 100 microseconds
large(3):  200 microseconds

This object specifies the percentage of the total radio PHY bandwidth
available to the ARQ engine. Some or all of this allocated bandwidth is
used to when detected errors are corrected. The percentage will be
approximated to the closest value supported by the ARQ engine.

This object identifies the latency value for voice data.

This object specifies the expected latency values for data.
Reducing the latency, provides the ARQ engine less time to correct
codeword errors. So if latency is reduced sufficiently, the data
throughput will get effected.
Also note that the latency values on both ends of the link should
be kept identical, else the data throughput will be effected.

This object specifies the maximum number of consecutive ARQ codewords
that will be transmitted. ARQ codewords are transmitted for error
correction. When an ARQ codeword is transmitted, a data	codeword
cannot be transmitted in that time slot, resulting jitter on the
received data stream.
Lower the value of the burst size, lower the peak jitter values.

This object specifies the typical error free bit rate that is possible
on this	link given the current configuration as specified in the
cwrRadioPhyTable. If the radio channel is excessively noisy then the
bit rate will be lower than this value

This object specifies the minimum error free bit rate that is supported
on this	link given the current configuration as specified in the
cwrRadioPhyTable and the settings in this table.

This object specifies the maximum latency jitter introduced by the ARQ
engine, based on the settings defined in this table.

This object when set to true will force the PHY quality
parameters to be reset from the cwrRadioPhyTable.
Reading this object will always return false. This is useful
when arbitrary changes to the ARQ parameters have to be reset
to known consistent valid values.

This object when set to true will enable the Automatic Repeat Query
subsystem. Disabling the ARQ subsystem disables a major error
correction mechanism of the radio, due to which an operating
radio PHY may suffer large performance degradation.

This object identifies the number of 1 byte errors that were corrected
since the the radio link reached linkOperational state.

This object identifies the number of consecutive 2 byte errors that
were corrected since the the radio link reached linkOperational state.

This object identifies the number of consecutive 3 byte errors that
were corrected since the the radio link reached linkOperational state.

This object identifies the number of consecutive 4 byte errors that
were corrected since the the radio link reached linkOperational state.

This object identifies the number of consecutive 5 byte errors that
were corrected since the the radio link reached linkOperational state.

This object identifies the number of consecutive 6 byte errors that
were corrected since the the radio link reached linkOperational state.

This object identifies the number of consecutive 7 byte errors that
were corrected since the the radio link reached linkOperational state.

This object identifies the number of consecutive 8 byte errors that
were corrected since the the radio link reached linkOperational state.

This object identifies the number of consecutive 9 byte errors that
were corrected since the the radio link reached linkOperational state.

This object, along with ifIndex,  represents the index of this entry
in the cwrRfTable.

This object represents the index into CwrRfEntityTable. This index
identifies the radio frequency resource.

This object indicates if this RF resource is being used to either
receive, transmit, or both.

This object represents the minimum frequency at which this RF resource
can transmit.

This object represents the maximum frequency at which this RF resource
can transmit.

This object represents the lowest transmission frequency this RF
resource can receive. 

This object represents the highest transmission frequency that this
RF resource can receive.

This object represents the minimum power that the RF subsystem
can supply the antenna. 

This object represents the maximum power that the RF subsystem can
supply the antenna.

This object represents the state of the transmit oscillator. The
oscillator must be in oscillatorOk(1) state for the system to function
properly.

This object represents the index into the cwrAntennaTable. This
object may be 0 if the cwrAntennaTable is not available.

This object represents the state of the receive oscillator. The
oscillator must be in oscillatorOk(1) state for the system to function
properly.

This object represents the current temperature of the RF unit.

This object specifies whether the voltage supply to the RF unit is
within specifications or not.

This object specifies whether the RF resource is functioning properly
or not. If it is functioning properly then it will be online(1),
else offline(2).

Each RF resource has an associated control channel.
The control channel is used to send/receive control information to the
RF resource. For the RF resouce to operate properly, the control
channel must be established.
This object indicates the status of the control channel
ok(1)    - RF resource may be controlled successfully
notOk(2) - Cannot talk to the RF resource.

This object indicates the range or burst sizes supported by the ODU.
This information is read from the ODU EEPROM.  The user may set the
cwrBurstSize MIB object in the cwrRadioPhyTable based on the value
of this object.

This object represents the state of the IF transmit oscillator. The
oscillator must be in oscillatorOk(1) state for the system to function
properly.

This object represents the state of the IF receive oscillator. The
oscillator must be in oscillatorOk(1) state for the system to function
properly.

This object represents the state of the IF reference oscillator. The
oscillator must be in oscillatorOk(1) state for the system to function
properly.

This object represents the index into CwrIntFreqEntityTable.
It identifies the intermediate frequency resource.

This object represents the IF input frequency.

This object represents the IF output frequency.

If the number of Codeword Errors detected in a duration of 1
Operational second, is greater than this value then that second is
counted as an Errored Second.

This object specifies low degraded second threshold.
When the number of codeword errors detected are greater or equal
than this value and less than cwrLinkHighCwDSThresh
then that second is counted as a Codeword Degraded Second.

This object specifies high degraded second threshold.
When then number of codeword errors detected are greater than
this value then that second is counted as a Codeword Severely Errored
Second.

When the number of severely errored codewords detected consecutively
in one second equals this threshold value, the second is counted
as a Consecutively Severely Errored Second.

This object specifies the one hour Codeword Error Second threshold.
When the number of Codeword Error Seconds in a 1 Operational Hour
period exceeds this limit cwrTrapLink1HrThresh trap will be generated.
Time measurement starts	after the first operational second.

This object specifies the one hour Codeword Severely Errored Seconds
threshold. When the number of Codeword Severely Errored Seconds in a
1 Operational Hour period exceeds this limit cwrTrapLink1HrThresh trap
will be	generated. Time measurement starts after the first operational
second.

This object specifies the one hour Codeword Consecutively Severely
Errored Seconds	threshold. When the number of Codeword Severely Errored
Seconds in a 1 Operational Hour period exceeds this limit
cwrTrapLink1HrThresh trap will be generated.
Time measurement starts	after the first operational second.

This object specifies the one hour Degraded Codeword Minute
threshold. When the number of Degraded Codeword Minutes in a 1
Operational Hour period exceeds this limit cwrTrapLink1HrThresh trap
will be generated.
Time measurement starts	after the first operational second.

This object specifies the 24 hour Codeword Error Second threshold.
When the number of Codeword Error Seconds in a 24 Operational Hour
period exceeds this limit cwrTrapLink24HrThresh trap will be generated.
Time measurement starts	after the first operational second.

This object specifies the one hour Codeword Severely Errored Seconds
threshold. When the number of Codeword Severely Errored Seconds in a
1 Operational Hour period exceeds this limit cwrTrapLink24HrThresh trap
will be	generated.
Time measurement starts	after the first operational second.

This object specifies the one hour Codeword Consecutively Severely
Errored Seconds	threshold. When the number of Codeword Severely Errored
Seconds in a 1 Operational Hour period exceeds this limit
cwrTrapLink24HrThresh trap will be generated.
Time measurement starts	after the first operational second.

This object specifies the one hour Degraded Codeword Minute
threshold. When the number of Degraded Codeword Minutes in a 1
Operational Hour period exceeds this limit cwrTrapLink24HrThresh
trap will be generated.
Time measurement starts	after the first operational second.

This object represents the number of Available Seconds cumulated
since the link was powered up. It is equal to:
Error Free Seconds + Errored Seconds - Severely Errored Seconds.

This object represents the number of seconds that the link was
not available for use. It is equal to:
Severely Errored Seconds + Sync Loss Seconds.

This object represents the number of Link Admin Up Seconds during
which the radio link was out of sync with the remote end.

This object represents the ratio of cumulative Codeword Error Free
Seconds (EFS) to Link Admin Up seconds, expressed as a percentage.

This object represents the ratio of cumulative Codeword Errored
Seconds (ES) to Link Admin Up seconds, expressed as a percentage.

This object represents the ratio of cumulative Codeword Severely
Errored Seconds (SES) to Link Admin Up seconds, expressed as a
percentage.

This object represents the ratio of cumulative Available seconds to
Link Admin Up seconds, expressed as a percentage.

This object represents the ratio of cumulative Codeword Degraded
Minutes to Link Admin Up seconds, expressed as a percentage.

This object represents number of times the radio link successfully
synchronized with the far end.

This object represents number of times the link attempted to
synchronize with the far end but failed to.

This object represents number of times the radio link layer was
shutdown by operator intervention or a higher layer protocol.

This object represents number of times the radio link was synchronized
but lost synchronization with the remote end without manual or
higher layer protocol layer intervention.

This object represents elapsed time since the radio link
successfully synchronized with the remote end.

This object represents elapsed time since the radio link
lost synchronization with the remote end.

This object represents the effective data throughput of this link
while the link was synchronized.

This object represents the ratio of total error free codewords received
to the total codewords received as a percentage.

Each entry represents the sum of the metrics from the previous 24
hour entry + the 24 hour period immdeiately prior to the most recent
update.

This object represents time in seconds since system power up at which
time this entry was updated.

This object represents the cumulative Codeword Error Free Seconds (EFS)
detected since link power up, captured at cwr24HrUpdateTime.

This object represents the number of Codeword Error Seconds (ES)
detected since link power up, captured at cwr24HrUpdateTime.

This object represents the number of Codeword Severely Error Seconds
(SES) detected since link power up, captured at cwr24HrUpdateTime.

This object represents the number of Codeword Consecutively Severely
Error Seconds (CSES) detected since link power up, captured at
cwr24HrUpdateTime.

This object represents the number of Codeword Degraded Minutes (DM)
detected since link power up, captured at cwr24HrUpdateTime.

This object represents the total number of errored codewords
detected since link power up, captured at cwr24HrUpdateTime.

This object represents the total number of codewords
received on this link since link power up, captured at
cwr24HrUpdateTime.

Each entry represents the sum of the metrics from the previous 1 hour
entry + the 1 hour period immdeiately prior to the most recent update.

This object represents time in seconds since system power up at which
time this entry was updated.

This object represents the cumulative Codeword Error Free Seconds (EFS)
detected since link power up, captured at cwr1HrUpdateTime.

This object represents the cumulative Codeword Errored Seconds
(ES) detected since link power up, captured at cwr1HrUpdateTime.

This object represents the cumulative Codeword Severely Errored Seconds
(SES) detected since link power up, captured at cwr1HrUpdateTime.

This object represents the cumulative Codeword Consecutive Severely
Errored	Seconds (CSES) detected since link power up,
captured at cwr1HrUpdateTime.

This object represents the cumulative Codeword Degraded Minutes
detected since link power up, captured at cwr1HrUpdateTime.

This object represents the cumulative errored codewords detected
since link power up, captured at cwr1HrUpdateTime.

This object represents the cumulative total received codewords
detected since link power up, captured at cwr1HrUpdateTime.

Each entry represents the sum of the metrics from the previous 1
minute entry + the 1 minute period immdeiately prior to the most recent
update.

This object represents time in seconds since system power up at which
time this entry was updated.

This object represents the cumulative Codeword Error Free Seconds (EFS)
detected since link power up, captured at cwr1MinUpdateTime.

This object represents the cumulative Codeword Errored Seconds
(ES) detected since link power up, captured at cwr1MinUpdateTime.

This object represents the cumulative Codeword Severely Errored Seconds
(SES) detected since link power up, captured at cwr1MinUpdateTime.

This object represents the cumulative Codeword Consecutively Severely
Errored Seconds	(CSES) detected since link power up, captured at
cwr1MinUpdateTime.

This object represents the cumulative Codeword Degraded Seconds (DS)
detected since link power up, captured at cwr1MinUpdateTime.

This object represents the cumulative errored codewords detected
since link power up, captured at cwr1MinUpdateTime.

This object represents the cumulative total received codewords
detected since link power up, captured at cwr1MinUpdateTime.

Each entry represents the sum of the metrics from the previous
1 second entry + the 1 second period immdeiately prior to the
most recent update.

This object represents time in seconds since system power up at which
time this entry was updated.

This object represents the cumulative total number of codewords
received by this radio link at the time this entry was updated.

This object represents the cumulative uncorrectable codewords
emitted by the Reed-Solomon error correction engine at the time
this entry was updated. This is also called Pre ARQ codeword error.

This object represents the cumulative number of uncorrectable
codewords consumed by the Automatic Repeat Query error correction
engine at the time this entry was updated. This is also called as
Post ARQ codeword error.

This represents the cumulative number of unique RR's (Retransmit
Requests) received (from the remote end) at the time this entry was
updated.
The remote end issues a Retransmit Request if it receives an
uncorrectable codeword.

This object represents the cumulative number of RRs
(Retransmit Requests) that were serviced at the time this entry was
updated.

This object represents cumulative number of unique ARQ's that
were received by the transmit side of the local end at the time
this entry was updated.
This provides an indication of how error free the transmisisons of
the local end of the link are from the the remote end's perspective.

This object represents cumulative number of ARQ's that were serviced
at the time this entry was updated.
A serviced ARQ results in a re-transmitted codeword.

This object represents the cumulative number of corrected sync byte
errors, at the time this entry was updated.

This object represents the size of the larget block of consecutive
codeword errors received since this entry was last updated.

This object represents the cumulative number of error free codewords
emitted by the Automatic Repeat Query error correction engine at
the time this entry was updated. Also called as	Post ARQ
good codewords.

This object, along with ifIndex, is the index into this table
and represents one entry in the table. The entry in this table
for which cwrHistIndex = x is associated with the entry in
cwrHistSummaryTable and the entry in cwrHistDataTable for
which the index variable in those tables has the same value, x.

This object represents the attribute that is being histogrammed.

This object identifies the RF resource for which this histogram
specification applies. If this is 0, the agent will automatically
use the most logical value for the specified cwrHistClass. If 0 has
been specified then on reading this object the agent will return the
RF resource id for which the histogram is being captured.

This object identifies the DSP on which to create the histogram.
If 0 is specified then the agent will automatically use the most
logical DSP for the specified cwrHistClass parameter.
If 0 has been specified then on reading this object the agent will
return the DSP number that is being used to capture this histogram.

This object represents the maximum of the values that will be
collected in the first bin of the histogram.
All values < cwrStartBinValue will be kept in the first histogram bin.

This object represents the range of values of the sampled data that
should be accounted for in one histogram bin. For example all data
samples between x..y (where y = x + cwrBinDelta - 1), will be
counted and placed in the same bin.

This object represents total number of bins to be created for the
histogram.

This object represents rate at which snapshots of the histogram will be
available.

This object specifies the duration for which this histogram must
be accumulated. After successfully accumulating data for this amount
of time the collection stops and the cwrHistStatus changes
to statusCaptured.

This object identifies management station that created this
histogram specification.

This object represents the number of bits by which the signal count
is right shifted before it is stored in the histogram bin.
This provides a mechanism to uniformly scale the collected histogram
to account for overflows.

This object identifies which tone in a burst should be sampled for
capturing the data.
cwrCirculate(1):
The successive tones will be used for every successive burst.
cwrAverage(2):
The value of every tone in a burst will be averaged.
cwrspecific(3):
The identified tone is used.

If cwrHistToneSelection is cwrSpecificTone then this object
identifies tone that should be used for sampling.

This object represents the action to be carried out on this
histogram specification. If a histogram has been successfully
captured then it must be cleared before an other capture
may be initiated.

This object represents the current state of this histogram collection
Once the histogram collection is complete the status changes
statusCaptured and the data is available for use.
None of the parameters of a histogram specification may be modified when
the specification is in statusInProgress.
A statusCaptured or statusStopped histogram must be actionClear'ed
before another histogram specification may be started.
The histogram may be read accurately between the cwrUpdateRate
intervals. If the read spans across the update time data from the
previous and current updates can be mingled.

This object may be used to create or delete a histogram control
specification.

The histogram data is updated every cwrUpdateRate seconds.
When this object is set to true(1), the latest histogram data set
is summed with the previous histogram data set and the
cwrHistSummaryTable will reflect cumulative values.
When set to false(2), only the latest data set is made available
and the cwrHistSummarytable will reflect the latest values.

This object represents the time in seconds since power up when
this histogram snapshot was retrieved from the hardware.

This object represents the minimum value of the data sample seen for
this histogram.

This object represents the maximum value of the data sample seen for
this histogram.

This object represents the arithemetic mean of the data sample values for
this histogram.

This object represents the histogram bin number for the value
in cwrValue.

This object represents the value in the histogram bin
cwrHistBinIndex.

This object, along with ifIndex, identifies this entry.

This represents the attribute of a radio link which needs to be
thresholded. For each of these attributes, the cwrThreshType identifies
the type of change to monitor. When that threshold is exceeded a
Trap with appropriate parameters will be generated.

This object represents the kind of change that needs to be monitored
for the cwrThreshAttribute. An event is generated when the following
condition is met.

This object identifies the RF resource for which this threshold
should be defined.

This object represents the value to be compared against. The
cwrThreshType determines the way in which it is used.
It is used as follows:
if cwrThreshType is ..
highThresh : Notify if data sample exceeds the cwrThreshValue.
lowThresh  : Notify if data sample recedes below the cwrThreshValue.
upChange   : Notify if data sample increases by more than
cwrThreshValue.
downChange : Notify if data sample decreases by more than
cwrThreshValue.
upLimit    : Notify if data sample crosses cwrThreshValue while
increasing in value.
lowLimit   : Notify if data sample crosses cwrThreshValue while
decreasing in value.

When radio signals oscillate around threshold values, they potentially
flood the system with notifications. This object specifies the amount
of time to wait before sending an identical notification if the
oscillations continue.  Notifications are not generated due to any
threshold value which is reached/exceeded/crossed/etc. during this
wait time

This object specifies the amount of time for which the radio signal
should stabilize before a trap is sent to indicate that the radio
signal has stabilized.

This object indicates the DSP used to monitor this threshold.

This object represents the status of this threshold entry. It may be
used to create a new threshold specification.
For every cwrThreshAttrClass one threshold of cwrThreshType on one
DSP may be created.

This object, along with ifIndex, is the index into this table
and represents one entry in the table. The entry in this table
for which cwrTlIndex = x is associated with the entry in
cwrTlSummaryTable and the entry in cwrTlDataTable for
which the index variable in those tables has the same value, x.

This object represents the attribute for which a timline capture
is requested.
When a timeline is requested, cwrTlNumDataValues worth of data will be
captured.

This object identifies the RF resource for which this timeline
specification applies.
If this is 0 then the agent will automatically the most logical
value for the specified cwrHistClass. If 0 has been specified
then on reading this object the agent will return the
RF resource id for which the timeline is being captured.

This object identifies the DSP on which this timeline needs to be
captures.
If 0 is specified then the agent will automatically use the most
logical DSP for the specified cwrTlClass parameter.
If 0 has been specified on create then on reading this object the
agent will return the DSP number that is being used to capture
this timeline.

This object indicates the number of data values to be captured for
this timeline.  The captured data can be viewed by reading the
cwrTlDataTable.

This object represents the number of successive data samples to be
added and returned. This enables larger data sets to be captured even
with limited cwrTlNumDataValues.

This object represents the number of bits by which the raw data
data should be right shifted before applying cwrTlDecimationFactor.
This provides a mechanims of controlling overflow due to summation.

This object identifies which tone in a burst should be used to
sample data for the timeline.
cwrCirculate(1):
The successive tone will be used for every successive burst.
cwrAverage(2):
The value of every tone in a burst will be averaged.
cwrspecific(3):
The identified tone is used.
DEFVAL { cwrAverage }

If cwrTlToneSelection is cwrSpecificTone then this object
identifies the tone that should be used for sampling.

This object specifies the index of the threshold that when triggered
will start the data capture for this timeline.
For a timeline data capture to be triggered by a threshold,
the threshold must be defined on the same DSP as the timeline.
If cwrTlThreshIndex is 0 then there is no threshold associated
with this timeline and the data samples are captured and returned
immediately. If cwrTlThresIndex is not 0, then the data samples
are captured when the threshold fires.

This object represents the action to be carried out on this
timeline specification. If a timeline has been successfully
captured then it must be cleared before an other capture
may be initiated.

This object represents the current state of this timeline collection
Once the timeline collection is complete the status changes
statusCaptured and the data is available for use.
None of the parameters of a timeline specification may be modified when
the specification is in statusInProgress.
A statusCaptured or statusStopped histogram must be actionClear'ed
before another timeline specification may be started.

Once a trigger fires, this object determines which portion of the
collected data to capture for use. If it is:
preTrigger(1) : Then most of the data collected prior to trigger
is captured.
postTrigger(2): Then most of the data collected after the trigger
is captured.

This object may be used to create or delete a timeline control
specification.
Once created data sampling starts based on the value of
cwrTlAction. The data capture depends on the value of
cwrTlThreshIndex.
The actual data is collected based on the cwrTlThreshIndex,
if cwrTlThreshIndex is 0 then there is no stop trigger associated
with this timeline and the data samples are captured and returned
immediately. If cwrTlThresIndex is not 0, then the data samples
are captured when the threshold fires.

This object represents the time in seconds since power up when
this timeline capture was completed.

This object represents the number of values available in the timeline.

This object contains the value of cwrTlValueIndex which represents
the entry in the cwrTlDataTable that caused the stop trigger to fire,
thereby resulting in this timeline to be collected.

This object, along with ifIndex and cwrTlIndex,  is the index
into the timeline data table.

This object represents the radio signal data sampled.

This object represents the DSP at which the snapshot needs to
be collected.

This object represents the attribute that is being snapshoted by
the hardware. When a snapshot request is issued up to 4 simultaneous
radio signal attribute may be captured at once.
The 4 attributes are specified by bit OR'ing the snapshot types
identified below. When a snapshot specification
is started all the specified attributes are captured simultaneously.
The TX and RX types cannot be mixed. RX, Sync types can be mixed.
When a snapshot request is issued up to four radio signal attributes
may be requested at once, one from each set:
===============================================
Type   Set1               Set2
===============================================
RX     y1n(x1)            y2n(x2)
H2k(x80)           H1k(x40)
-                  -
Sync   -                  FreqCorr(x8000)
-                  FLL_FFT_Sp(x20000)
TX     CodecIn(x200)      IFFTIn(x400)
===============================================
===============================================
Type   Set3                Set4
===============================================
RX     Y2k(x8)             Y1k(x4)
h1n(x10)            h2n(x20)
zhat(x100)          -
Sync   FreqOffCF(x2000)(*) BrstTimeCF(x1000)(*)
-                   TT_FCorr(x10000)
TX     -                   RoundOut(x800)
===============================================
(*)  BrstTimeCF cannot be mixed with Set2
(*)  FreqOffCF  cannot be mixed with Set1
Note that only the Tx* attributes may be captured on DSP's 1, 2.
The attributes are:
RxRawBurstAnt1Y1n(0x01):
This represents a snapshot of the received signal for RF
resource 1. For every sample the real and imaginary components
are captured.
Units: (I, q)
Value: 32 bit quantities.
RxRawBurstAnt2Y2n(0x02):
This represents a snapshot of the received signal for RF
resource 2. For every sample the real and imaginary components
are captured.
Units: (I, q)
Value: 32 bit quantities.
RxSpectrumAnt1Y1k(0x04):
This represents a snapshot of the spectrum of the received
signal for RF resource 1. For every sample the real and
imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
RxSpectrumAnt2Y2k(0x08):
This represents a snapshot of the spectrum of the received
signal for RF resource 2. For every sample the real and
imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
RxTimeDomainChannelAnt1H1n(0x10):
This represents a snapshot of the time domain channel
for RF resource 1. For every sample the real and
imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
RxTimeDomainChannelAnt2H2n(0x20):
This represents a snapshot of the time domain channel
for RF resource 2. For every sample the real and
imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
RxFreqDomainChannelAnt1H1k(0x40):
This represents a snapshot of the frequency domain channel
for RF resource 1. For every sample the real and
imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
RxFreqDomainChannelAnt2H2k(0x80),
This represents a snapshot of the frequency domain channel
for RF resource 2. For every sample the real and
imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
RxConstellationZHatk(0x100):
This represents a snapshot of the soft decisions.
For every sample the real and imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
TxCodecInput(0x200):
This represents a snapshot of input values to the Tx Code.
Units: Real values.
Value: 32 bit quantities.
TxIFFTInput(0x400):
This represents a snapshot of the IFFT signal for the
Transmitted data.
For every sample the real and imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
TxRoundOutput(0x800):
This represents a snapshot of the Rounded Constellation signal
for the Transmitted data.
For every sample the real and imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
SyncBurstTimeCostFunc(0x1000):
This represents the timing cost function for Sync bursts.
Units: Real values.
Value: 32 bit quantities.
SynFreqOffsetCostFunc(0x2000):
This represents a snapshot of the frequeny offsets.
For every sample the real and imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
SyncFllFreqCorrelation(0x8000):
This represents a snapshot of Frequency correlation.
For every sample the real and imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
SyncFllTrainToneCorrelation(0x10000):
This represents a snapshot of Frequency locked loop's Training
tone correlation.
For every sample the real and imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.
SyncFllFFTSpectrum(0x20000):
This represents a snapshot of Frequency locked loop, FFT
Spectrum.
For every sample the real and imaginary components are captured.
Units: (I, q)
Value: 32 bit quantities.

This object represents the action to be carried out on this
snapshot specification. If a snapshot has been successfully
captured then it must be cleared before an other capture
may be initiated.

This object represents the current status of this snapshot
specification. When the status in statusInProgress none of the
snapshot parameters can be configured. When the status is
statusCaptured then data is available for use.

This object may be used to create or delete this snapshot
specification.

This object represents the first snapshot attribute value.

This object represents the number of values captured for the snapshot
cwrSnapAttr1Id.

This object represents the second snapshot attribute value.

This object represents the number of values captured for the snapshot
cwrSnapAttr2Id.

This object represents the third snapshot attribute value.

This object represents the number of values captured for the snapshot
cwrSnapAttr3Id.

This object represents the third snapshot attribute value.

This object represents the number of values captured for the snapshot
cwrSnapAttr4Id.

This object represents the snapshot entry index number.

The data sample value. Real part.

The data sample value. Imaginary part if the attribute is represented
by a complex number.

This object represents the index of this entry in the cwrAntennaTable.

This object represents the dimension of the antenna in the
X direction.

This object represents the dimension of the antenna in the
Y direction.

This object represents antenna type for example 'dish-antenna'.

This object describes the antenna.

This object represents the gain of this antenna.

This object represents the electrirc polarization of the antanna.

This object represents the point in the system where the data signal
is looped back.
none(0)         - no loopback
codec(1)        - loopback at the Encoder/Decoder module. This exercises
the framer, and codec modules
framer(2)       - loopback at the 'framer' module.
fir(3)          - loopback at the 'Finite Impulse Response' module. This
exercises the framer, codec, and FIR modules.
if(4)           - loopback at the 'Internal Frequency' module using both
the main and the diversity receive paths.  This
exercises the framer, codec, FIR, and IF modules.
rf(5)           - loopback at the main RF unit via the main receive path
in the IF module. This exercises the framer, codec,
FIR, IF, and RF modules.
rfDiversity(6)  - loopback at the main RF unit but route it through the
diversity receive path in the IF module. This
exercises the framer, codec, FIR, IF, and RF modules.
ifMain(7)       - loopack at the IF module using only the Main receive
path.  This exercises the framer, codec, FIR, and
IF modules.
ifDiversity(8)  - loopack at the IF module using only the diversity
receive path.  This exercises the framer, codec, FIR,
and IF modules.

If set to true(1), then the DSP identified by cwrScopePortDsp, will
redirect a portion of the output signal for the attribute identified
by cwrScopeAttribute to the scope port.

This identifies the DSP that should redirect a portion of the
signal data to the scope port.

This represents the attribute to be redirected to the scope port.
The attributes that may be redirected to scope port is the same
as that identified in cwrSnapshotType.

The explanation string for the event trap cwrEventId.

This table contains information about the radio common to both the
transmit and receive sides.

This table contains information about the currently configured
physical layer.  These configuration paramters must match the
corresponding configuration parameter at the remote end for
the wireless link to be established.

This table contains information about the radio PHY quality control
parameters. Note that the parameters in this table are automatically
determined by the parameters configured in the cwrRadioPhyTable.
These parameters may further be used to tune the characteristics when
needed.

This provides information on the number of byte
detected and corrected by the ARQ engine.
The ARQ engine can correct up to 9 consecutive byte errors.
This table keeps a count of the number of byte errors corrected
over time.
The values in this table are cumulated from link power up.

This table contains information about the state of the radio frequency
resources used by the radio link.

This table contains information about the state of the intermediate
frequency subsystem on the wireless radio.

This table contains threshold values that are the trigger points for
controlling the collection of the Link Metrics such as Codeword Errored
Seconds	and others.

This table contains metrics used to measure the quality of the radio
link identified by the ifIndex. The metrics in this table are cumulated
since the last time the system powered up.

This table contains metrics collected over the duration of 24 hours.
This table is updated once every day for 32 days.   Therefore, this
table will have a maximum of 32 entries that provide cumulative status
of the link, identified by ifIndex.

This table contains metrics collected over the duration of one hour.
This table will have a maximum of 24 entries providing cumulative
status of the link, identified by ifIndex, over the past 24 hours.
This table is updated once every hour.

This table contains metrics collected over the duration of one minute.
This table will have a maximum of 60 entries providing cumulative
status of the link, identified by ifIndex, over the past 60 minutes.
This table is updated once every minute.

This table contains metrics collected over a duration of 1 second.
The data in this table is derived directly from the hardware.
This table will have a maximum of 60 entries providing cumulative
status of the link, identified by ifIndex, over the past 60 seconds.
This table is updated once every second.

This table contains information about histograms configured in
hardware. When data is collected it will be stored in histogram
bins as follows:
All values (X < cwrStartBinValue) will be kept in the first
histogram bin.
Subsequent values will be distributed in the bins based on the
cwrBinDelta. Last bin, will contain all values
(X > (cwrStartBinValue + (cwrNumBins - 2) * cwrBinDelta)),
i.e. any value that is greater than that may be stored in the
last bin.

This table contains histogram Summary collected based on the
specifications in the cwrHistCtrlTable.

This table contains histogram values collected based on the
specifications in the cwrHistCtrlTable.

This table provides facilities to establish thresholds for the radio
signals analyzed on the radio interface. A threshold identified in this
table may be used to trigger a timeline capture in the cwrTlTable.

This table contains information about timelines configured in
hardware. The number of data values captured for each timeline
is configured by setting the variable cwrTlNumDataValues. The captured
data values can be retreived by reading the cwrTlDataTable.

This table contains Timeline Summary collected based on the
specifications in the cwrTlCtrlTable.

This table contains data values collected for the timelines
specified in the cwrTlCtrlTable.  The number of data values
displayed for each timeline is determined by the value specified
for cwrTlNumDataValues in cwrTlCtrlTable.

This table contains information about the snapshots configured in
hardware. When data is collected it will be stored in
cwrSnapDataTable.

This table contains summary information for captured snapshots
defined in cwrSnapshotCtrlTable.

This table contains snapshot values collected based on the
specifications in the cwrSnapshotCtrlTable.

This table contains information about the antenns available for
use.

This table provides facilities to establish loopback points in the
radio hardware to exercise various sections of the hardware.

This table provides facilities to redirect a portion of the signal
being processed by a DSP to a scope port on the radio. An
oscilloscope may be connected to the scope port to analyze the
signal.

This table provides information about the last trap that was
generated on this interface.

The radio subsystem has detected that the combination of the
configuration parameters that has been requested is inconsistent
and cannot be supported.
The cwrTrapReason is the textual description of what parameter causes
the mismatch.

The radio subsystem has failed to initialize the hardware successfully.
This implies that there is a critical error condition in the associated
hardware. The cwrTrapReason specifies the reason the init failed.

The radio subsystem has detected a significant change in
the radio link quality. The cwrTrapReason will describe
the quality.

The radio link has lost synchronization with the remote end.

The radio link has acquired synchronization with the remote end.

The IF receive frequency oscillator has changed state.

The IF transmit frequency oscillator has changed state.

The IF Reference Frequency oscillator has changed state.

The supply voltage to the RF resource has changed.
The cwrRfSupplyVoltageState specifies whether the supply voltage is
in spec or not.

The RF receive frequency oscillator has changed state.
The cwrRfIndex identifies the RF resource that is the cause
of this trap. The cwrRfRxOscState specifies the
state of the oscilator.

The RF transmit frequency oscillator has changed state.
The cwrRfIndex identifies the RF resource	that is the cause
of this trap. The cwrRfRxOscState specifies the
state of the oscilator.

The temperature of the RF module identified by cwrRfIndex
has exceeded a defined reference.

This trap indicates that the RF resource either
came online(1) or went offline(2).
The cwrRfIndex will identify which resource changed state
and cwrRfStatus will identify what state it is in.

One of cwrLink1HrESAlarmThresh, cwrLink1HrSESAlarmThresh,
cwrLink1HrCSESAlarmThresh, cwrLink1HrDCMAlarmThresh was
was exceeded. The cwrTrapReason will identify which
threshold was exceeded.

One of cwrLink24HrESAlarmThresh, cwrLink24HrSESAlarmThresh,
cwrLink24HrCSESAlarmThresh, cwrLink24HrDCMAlarmThresh was
was exceeded. The cwrTrapReason will identify which
threshold was exceeded.

The radio subsystem generates this trap when a threshold crosses
its specified limit. The parameters identify the following
cwrThreshValue          - The value that was crossed.
cwrThreshHysteresisTime - The Hysteresis time that was specified.
cwrThreshLimitTime      - The Limit time that was specified.

This is the MIB Module for the Cisco Wireless Radio
Point to Point interface specification.

Group of objects implemented to configure a point to point wireless
radio.  This includes the cwrBurstSize object.

Group of objects implemented to tune phy quality in the point to
point wireless  systems.

Group of objects implemented to tune phy quality in the point to
point wireless  systems.  This group includes cwrBurstSizeGroup.

Required Radio link metrics objects for the point to point wireless
systems.

Group of objects implemented in the point to point wireless
system for Testing the link.

Group of objects implemented in the point to point wireless
system for capturing histograms of radio signal parameters on the radio
interface.

Group of objects implemented in the point to point wireless
system for establishing thresholds and capturing timeline data.

Group of objects implemented in the point to point wireless
system for capturing snapshots of various parameters on the radio
interface.

Group of objects implemented in the point to point wireless
system for managing the antennas available in the system.

Group of objects implemented in the point to point wireless
system for tracking the number of errored bytes that were
automatically corrected.