Safety Instructions
DOC ID - 1987 • Rev 03 3 / 6
The Processor, RF XMIT, and Pairing LEDs flash,
indicating the module is reset.
To enable communication timer delay on zones 1 or 2:
1. Pair a sensor to zone 1 or 2.
Note: Complete the next step before adding another
sensor.
2. Press the Memory Reset button.
The zone’s yellow LED illuminates, signifying that the
2-minute communication timer delay is enabled for that
zone.
To disable communication timer delay on zones 1 or 2:
1. Enter Pairing Mode.
2. Trip the sensor on zone 1 or 2, and then immediately
press the Memory Reset button.
The zone’s yellow DLY LED extinguishes signifying that
the lockout delay is disabled for the zone.
LEDs
Pairing: The Pairing LED illuminates when the module is in
“Pair Mode” and is off when the module is in “Normal
Operation Mode”. If there are no zones learned the Pairing
LED flashes.
Processor LED: This LED flashes when the module is in
“Normal Operation Mode”.
RF XMIT LED: The RF XMIT LED illuminates when RF
transmission is sent.
Zone LEDs: During "Normal Operation Mode" each LED
remains off until its representative zone is opened, then the
LED illuminates. At the beginning of "Pair Mode" all Zone
LEDs flash briefly, after which each Zone LED remains off until
the zone is learned in and then it turns on and remains on until
"Pair Mode" is complete.
DLY LEDs: Zones 1 and 2 each have a DLY LED. When a
zone’s DLY LED is illuminated yellow, that zone has the
2-minute communication timer delay enabled. When the DLY
LED is off, that zone’s communication timer delay is disabled.
When the DLY LED is flashing, the associated zone is tripped,
and the 2-minute communication timer delay is in effect. All
additional triggers from that sensor are ignored for 2 minutes.
Testing the module
Verify that the module and zones are working correctly.
To test the module/zones:
1. Set the panel to the sensor test mode.
2. Trip each zone on the module one at a time. Monitor the
system after tripping the zones.
Refer to the ClareOne Wireless Security and Smart Home
Panel User Manual (DOC ID 1871) for specific test
information.
Determining EOL resistance and
sensor type
In some instances, it is not visually apparent what is physically
connected to a zone in terms of any pre-existing EOL resistors
and whether the sensor is N/O or N/C. Use a multimeter to
learn this information.
With a sensor in its active state (i.e. door/window contact is
separated from its magnet), take a multimeter set to measure
resistance and connect the multimeter across the zone wires. If
the multimeter reads a value of 10kΩ or less, the sensor is
N/O, if the multimeter reads an open or extremely high
resistance (1Ω or higher) than the sensor is N/C. The table
below provides guidance for using the measurements to
determine the EOL resistance value, as well as the line
resistance for N/O sensors. This is the case regardless of the
number of sensors connected to a single zone, so long as all
sensors on the same zone are in series or in parallel with one
another.
Note: The module will not work if there is a combination of
series and parallel sensors connected to the same input zone.
Multimeter reads for
N/O
Multimeter reads for
N/C
Sensors active
(sensor away from
the magnet)
Value for EOL resistor
Open
Sensors inactive
(Sensors connected
to the magnet)
Value of line resistance
(10Ω or less)
Value of EOL resistor
plus line resistance
EOL resistance on existing installations typically ranges from
1kΩ - 10kΩ while line resistance should be 10Ω or less.
However, there may be some installations that do not have any
EOL resistors installed and the measured EOL resistance may
be the same as the line resistance. If there is no EOL resistor
installed than simply installing the provided 4.7kΩ resistor is all
that is needed. Ideally, any existing EOL resistors would be
removed and replaced with a 4.7kΩ resistor. If that is not an
option, additional resistors must be appropriately added, to get
the EOL resistance to 4.7kΩ. For more information, refer to the
ClareOne 16 Zone Wired Input Manual (DOC ID 1992).