Honeywell nfs2-3030 Programming Manual page 134

Fire alarm control panel

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CBE: Zones and Equations

Example: XZONE(Z02)

If any combination of two or more initiating devices that have been mapped to this software

zone come into alarm, then outputs mapped to this zone will activate.

•

The "RANGE" Operator

Each argument within the range must conform to the requirements of the governing function.

The range limit is 20 consecutive arguments.

Example: AND(RANGE(Z1,Z20))

Zone 1 through Zone 20 must all be active to activate the logic zone.

•

The "DIS(point argument)" Operator

Requires that the point argument be disabled for the operator to go active.

•

The "PRE(point argument)" Operator

Requires that the point argument be in prealarm for the operator to go active.

Example: AND(L1D1,PRE(L1D2))

The detector at address L1D1 must be active and the detector at L1D2 must be in prealarm for

this equation to go active.

•

The "SUP(point argument)" Operator

Requires that the point argument be in an active supervisory state for the operator to go active.

Example: OR(L1D1,SUP(L1M1))

The detector at address L1D1 must be active, or the module at L1M1 must be in an active

supervisory state, for the equation to go active.

•

The "FIRE(point argument)" Operator

Requires that the point argument be in an active fire alarm state for the operator to go active.

Example: AND(L1D1,FIRE(L1M1),FIRE(L1M2))

The detector at address L1D1 must be active, and the modules at L1M1 and L1M2 must be in

an active fire alarm state, for the equation to go active.

•

The "NON(point argument)" Operator

Requires that the point argument be in an active non-alarm state for the operator to go active.

Example: AND(L1D1,NON(L1M1))

The detector at address L1D1 must be active, and the module at address L1M1 must be in an

active non-fire alarm state, for the equation to go active.

•

The "SEC(point argument)" Operator

Requires that the point argument be in an active security alarm state for the operator to go

active.

Example: AND(L1M1,SEC(L1M2))

The module at address L1M1 must be active, and the module at address L1M2 must be in an

active security alarm state, for the equation to go active.

Time-based Functions

The panel supports three time-based functions: DEL, SDEL, and TIM. Special rules apply to an

equation containing a time-based function:

• Only one time-based function may be used in an equation.

• The time-based function must appear only once, as the first entry of the equation.

• It may not be nested within parentheses in the equation.

• Logic functions may be used in an equation that begins with a DEL or SDEL time-based

function: however, they must appear within parentheses following the time-based function.

Delay and duration times are in 24-hour format (HHMMSS); the allowable range is 00:00:00 to

23:59:59.

The "DEL" Function

134

NFS2-3030 Programming Manual — P/N 52545:K1 03/20/2012

Equations

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Honeywell nfs2-3030 Programming Manual page 134

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