3 scte-hms mib alarms, 1 scte-hms configurable alarms, Section 6.3 – Alpha Technologies AlphaNet DSM Series DOCSIS User Manual

34

745-814-B0-001, Rev. A

6.0

Data Management, continued

6.3 SCTE-HMS MIB Alarms

The HMS discrete and analog alarms provide the capability to monitor and alarm various

power supply and environmental conditions and measurements. The alarms in the MIB tables

can be defined and set to provide a custom monitoring system.

6.3.1 SCTE-HMS Configurable Alarms

The SCTE-HMS MIB tables can be configured to send SNMP traps to a network

management system in response to certain power supply conditions. The tables

used to define these alarms are the

propertyTable and the discretePropertyTable,

which are both located in the

propertyIdent MIB at OID 1.3.6.1.4.1.5591.1.1. When

an alarm condition is detected in either of these tables, an entry is created in the

alarmTable, and an alarmEvent SNMP trap is sent by the transponder to the SNMP

trap address.

propertyTable: Analog Alarms

Each variable in this table corresponds to an analog value of the power supply. The

alarms are disabled by default, and may be enabled and configured to suit monitoring

preferences. Each entry in the propertyTable has four possible alarm threshold levels:

Threshold Level Definition
LOLO

alarm threshold for extreme low condition

LO

alarm threshold for low condition

HI

alarm threshold for high condition

HIHI

alarm threshold for extreme high condition

There is also a ‘Deadband’ setting used as a buffer to prevent alarm oscillation when

the analog value transitions from an alarm state to a non-alarm state. The value must

exceed the alarm threshold by the amount of the deadband value before the alarm

will clear.

An alarm for a parameter in the table is enabled by setting its ‘alarmEnable’ bit-mask.

By setting the bits, the user can define which threshold levels are enabled. A “1” in a

bit position indicates the threshold level is enabled. This bit mask is converted to Hex

within the table.

For example, to set an alarm for only HI level values of a parameter, then set Bit 2 to

“1”, represented by 00000100 binary, or 04 Hex. To set alarms for all threshold levels,

enable Bits 0 through 3 by setting them to “1” represented by binary 00001111, or 0F

Hex.

See the table and example on the next page.

NOTE:

• Some programs, such as MG-Soft, use a Hex notation where 0F, for example, is rendered 0x0F. There is

no difference in the binary meaning of this notation.

• Most of the values in the propertyTable are scaled 1/100. For example, 43V is rendered 4300. See Table

6-4.