DESRIPTION: This product is a multi-criteria sensor incorporating 3 separate sensing elements. n IR photo diode for measuring ambient IR light levels (welding probability as well as signatures from flame), a photo electric sensing chamber for measuring smoke products of combustion and two thermistors on opposite sides of the sensor to monitor for heat. It is mechanically and electrically compatible with the existing 500 Series intelligent system, and works correctly when installed in a 200/500 Series system. The same product can be factory programmed to work in an Enhanced protocol system as well. Please refer to the Reference Table below for details regarding 500 Series, dvanced and Enhanced protocol. The product in its 500 series compatibility mode operates in a similar way to the multicriteria photo/thermal sensor regarding its decision levels. It can be factory programmed to use the same type code as the photo/thermal or a different type code, depending on the requirements of the customer. While maintaining backward compatibility, the dvanced protocol provides expanded capabilities, including bi-directional digital communication, the possibility to address up to 159 sensors, interrupt feature, group polling format for fast response to alarm conditions and improved power delivery. The tens digits go from 0 to 15 and the units from 0 to 9. The decimal address corresponding to each code switch knob address configuration can be calculated by multiplying the tens by ten and adding the units to the result. The remote output and internal LED can be controlled separately either by 500 Series (see Separate operation of remote output paragraph) or advanced protocol commands. The dvanced protocol defines two modes of communication, designated Direct Poll and Group Poll: these two modes communicate either with one device at a time or simultaneously with a group of devices. 1 of 27
This protocol contains a rapid alarm or fault detection feature which enables any device to signal the control panel when the device detects an alarm or fault condition. The alarm/fault condition represents a condition in the device which has been defined to require attention from the panel. This signal can be generated by any device where an alarm or fault condition occurs. This feature is disabled by default, but can be enabled by special commands. The external EEPROM can be read or written to by means of advanced protocol commands. Not all of the bytes are read and/or write accessible through the 200 series dvanced protocol (refer to EEPROM contents table). Four bytes in the EEPROM are used as a serial number, which can be read at panel start-up to detect double addresses. The digital units corresponding to PW4 and PW6 PW9 are multiples of 16 microseconds, i.e. 800 s corresponds to 50 digital units, or 2400 s to 150 digital units (for a device with 300 s time base). The detector includes a new (compared to mask 4 photo/thermal sensors) drift compensation algorithm in the photoelectric chamber to last longer without cleaning. When drift compensation has reached its limit (Drift Limit) a unique signal is generated in PW4 signifying this state. Until this value is reached, the PW4 value will increase steadily from the nominal initial value towards the drift alarm value, so that the user can readily see the status of the photo chamber. The unprocessed raw photo chamber value can be available in PW6 (see fig.4) corresponding to the data range shown in the Drift ompensation onstants table, without the internal processing. The same data can be read by the panel through appropriate advanced protocol commands. Magnet test generates an alarm (level 5 or level 6) unless the device determines it is incapable of alarming (photo, thermistor, IR fault). The device will then enter an algorithm bypass mode for the next 10 minutes: all delays/filters on the optical processing are temporarily removed. t this time the processing of the signal is limited so that canned smoke can easily and quickly cause an alarm signal, enabling easier verification of the multicriteria sensor s operation. fter 10 minutes the device returns to its normal operation. There is a provision for determining whether an alarm is due to heat (Level 6). This allows the control panel to ignore smoke alarms during periods of time while still offering some level of detection. In 500 series protocol, a unique sequence of control commands is required to enable this option in the detector. 2 of 27
To enable Level 6, the control panel needs to communicate to the device once with control bits 10 and 12 set to 00 followed by a single communication with control bits 10 and 12 set to 01, respectively. In 500 series protocol, once enabled, Level 6 can be disabled by repeating the above sequence. When enabled, PW2 will be three times PW1 for a single communication. When disabled, PW2 will be four times PW1 for a single communication. The status of the thermal alarm provision will be stored in EEPROM therefore the panel will not need to reconfigure the device after power loss. Enabling this function will also enable a second maintenance alert level when the photoelectric sensor s drift compensation has reached 80% of its limit. In this case a unique signal will be given in PW4/sub-address 0. When Level 6 is enabled the magnet test alarm level is level 6. In 200 series advanced protocol, level 6 and 80% drift alert are enabled by factory default. In 500 series protocol, the sensor can provide the panel with the highest instantaneous value of the two thermistors. This is given by PW7 according to the following formula: PW7 = (T + 87) x 8 (see Figure 5), where T is the highest temperature (elsius degrees) of the thermistors and units are microseconds. For example at 25, PW7 is about 896 s. This feature is factory programmable only. In 200 series advanced, the two thermistor values are available in sub-address 2 and 3. The temperature of the environment can be quite different from the temperature detected by the thermistors, due to thermal lag. The sensor provides an ambient IR level proportional output on PW9/sub-address 4 (see Fig.7). The sensor has wide light dynamic capability thanks to an utomatic Gain ontrol circuit which is suitable for most environment/light levels. Direct sun light ( such as mirror reflection) or strong IR light sources directed towards the detectors might saturate the IR sensor. There is a value in PW4/sub-address 0 to indicate a light saturation condition. fault will also be indicated after the predetermined time indicated in the specification. The transmission of PW6, PW7, and PW9 is determined by a setting in EEPROM. If the relevant bit is set, then all 3 PWs can be sent, if the bit is not set, then none of these PWs are sent. 3 of 27
SENSITIVITY ND NUISNE IMMUNITY The product provides 6 levels of sensitivity, which are categorized as below: Level 1 1%/ft of smoke. No delays from processed photo output. Level 2 2%/ft of smoke. No delays from processed photo output. Level 3 3%/ft of smoke. Time elapsed from smoke detection is within 45 Level 4 3%/ft of smoke. Time elapsed from smoke detection is between 45 and 1 30. Level 5 3%/ft of smoke. Time elapsed from smoke detection is greater than 1 30. Level 6 Heat only alarm. If the heat level on either thermistor exceeds 60 or rate of rise limits. Note: the delay counter starts when the smoke level exceeds approximately 0.75%/ft. The panel threshold should be chosen according to the specific environment: ULTR-LEN environments can use Level 1 LERT LEN environments can use Levels 2-3 LRM MODERTE environments can use Level 4 LRM HRSH environments can use Level 5-6 LRM 4 of 27
When advanced protocol is used an application suitable for different harsh environments may be selected according to the following application table: pplication number 0 0 Environment description Possible nuisance Problem Suggested Panel threshold LRM Hotel bedroom near shower Steam and rate of rise in heat from Level 4 opening bathroom door causing alarm. Detector installed close to bathroom door. Boiler rooms Dust and rate of rise heat causing Level 4 false alarms. Student dormitories, smoke from small appliance cooking Level 5 smoking hotel rooms or cigarette/etc. 1 2 Insect alarms Photo sensor only alarm. Level 5 ondensation in attics (and Photo sensor only alarm. Level 5 2 other normally unheated spaces e.g. pump houses, service intake rooms etc) 2 Heavy manufacturing larm from photo sensor due to dust/dirt. This application may include welding. 2 Strobes in industrial areas larm from photo sensor due to light dazzling and may include welding. Level 5 Level 4 dvanced application download effect removes heat enhancement so delays applied before alarm and reduces thermal ROR alarm slightly. removes heat enhancement so delays applied before alarm and reduces thermal ROR slightly raises smoke threshold to medium raises smoke threshold to maximum raises smoke threshold to maximum raises smoke threshold to maximum raises smoke threshold to maximum 3 Dusty environments and Settled dust turbulence in the chamber before drift alarm reached 3 HU rooms & lift motor rooms Synthetic smoke in 4 Discotheques and dazzling Photo sensor only alarm. Level 5 larm form photo sensor due to dust burst. Photo sensor alarm. an compromise drift compensation. Level 5 Level 5 raises smoke threshold to medium raises smoke threshold to medium raises smoke threshold to maximum 5 of 27
lights from strobes May also include smoking cigarettes. 4 Bar reas larm from photo sensor due to steam from glass washers and cigarette smoke. 4 Smoking area larm from photo due to cigarettes/etc. 5 ar parks and loading bay larm from photo and rate of rise with trucks having upward heat sensors. exhaust pipes or poor operating engines. Includes traffic build-up in cities. 5 Kitchens including industrial, canteens, and retirement homes. 6 Paint shops and repair shops larm from photo from burning foods and rate of rise sensors due to opening oven doors or turning ON burners. larm from photo and rate of rise sensors. This application may include welding and vehicles running inside building. 255 Vacuum cleaning Dust causing photo sensor only alarm. Level 5 Level 5 Level 5 Level 5 Level 5 Level 4 raises smoke threshold to maximum raises smoke threshold to maximum removes heat enhancement, changes thermal to fixed, and raises smoke to maximum removes heat enhancement, changes thermal to fixed, and raises smoke to maximum reduces heat enhancement in half and raises smoke threshold to maximum Default configuration: no effect 6 of 27
SEPRTE OPERTION OF REMOTE OUTPUT This feature is enabled by a global command to a non-existent address 253. With this global command, if all control bits are set to 0, then the detector accepts the command and redefines the action of the control bits on its normal polls, so that the LED and remote output can be separately controlled. If the control bits are all 1, then the device reverts to the standard LED control method. For only the next poll afterwards to any device that has seen and accepted this global command, PW2 will be 6xPW1 indicating that the remote output and LED are able to be separately controlled. When set to the standard LED control method, PW2 remains at 1xPW1. fter the remote output on command is first given, during the same poll, PW2 is 5xPW1. The priority of each of the different PWs where applicable and where they might be given simultaneously or in such a way to be contradictory are as follows: Highest 3xPW1-4xPW1-5xPW1-6xPW1-2xPW1-1xPW1 Lowest The status of the redefinition is lost when the device is powered off. On power up reset, the device goes to the standard LED control method. ll three control bits (10, 11 and 12) are used for controlling the LEDs when they are in the separately controllable state. The generation of PW5 on sensors is normally controlled by control bit 11, but in this mode, PW5 is always transmitted during the PW5 window. The possible combinations of control sequence are as follows: B10 B11 B12 LED Remote Remote Test output 0 0 0 ON ON# ON 0 0 1 ON ON# No hange 0 1 0 ON OFF@ ON 0 1 1 ON OFF@ No hange 1 0 0 OFF ON# No hange 1 0 1 BLINK ON# OFF 1 1 0 OFF OFF@ No hange 1 1 1 BLINK BLINK OFF This change of state requires two consecutive polls. @ This change of state requires two consecutive polls of remote output off # This change of state requires two consecutive polls of remote output on 7 of 27
VISIBILITY OF DRIFT OMPENSTION The multicriteria sensor provides the ability to last longer without cleaning by means of a drift compensation algorithm, which is based on the average photo chamber level compared with the current photo chamber level. In clean air, PW4/sub-address 0 reflects the drift compensation status, with 800 s for 0%, and 1200 s for 100%. The equivalent drift compensation range is in the 1.5 %/ft range. This means that the PW4/subaddress 0 value rises according to the amount of long-term chamber contamination until either the 80% drift level is reached, if this feature is enabled or until the 100% drift level is reached. While the detector is operating within the drift compensation range, its sensitivity to smoke is maintained. hanges in smoke level are not seen unless they are greater than the drift limit, ensuring that PW4/sub-address 0 values within the drift compensation range can never occur due to smoke. When the detector has reached or exceeded the 100% drift compensation range, the sensitivity to smoke will increase steadily as the chamber becomes more contaminated. TERMINL LYOUT Refer to Intelligent Base Product Spec. S00-003-XX 8 of 27
OMMUNITION SPEIFITIONS SPEIFITION TYP MIN MX UNIT OMMENTS ms Data Bit High Voltage Range (1) 5.0 4.5 5.5 V Recommended Panel Design Range Data Bit Low Voltage Range (1) 0 0.5 V Recommended Panel Design Range Bit Interval high Time (24V) 250 2000 s Bits 1-13: See Figure 1 Bit Interval low Time (0V, 5V) 250 2000 s Bits 1-13: See Figure 1 Software Reset Time 2750 2500 3000 s Minimum time to reset device (Figure 1) 4500 s dvanced protocol only (see Figure 2) EEPROM write extended software reset time 250 ms dvanced protocol only (see Figure 2) 1) ll specifications refer to conditions at the detector head 9 of 27
ELETRIL SPEIFITIONS SPEIFITION TYP MIN MX UNITS OMMENTS ommunication Line Supply Range 24 15 32 V D Panel Voltage Output Driver urrent (I f ) 58 40 70 m See Figure 3 Initial Output Driver urrent (I o ) 160 85 260 m See Figure 3 Output Driver Transition Time 55 30 170 s See Figure 3 Standby urrent @ 24VD Supply 200 No ommunication Standby urrent @ 24VD Supply 300 ommunication with LED blink enabled, once every 5s Standby urrent @ 24VD Supply 250 u Group poll with LED blink enabled, once every 0.1s LED urrent @ 24VD Supply 7 m ontinuous Operation urrent Supply Voltage to Guarantee LED on 16.5 V Initial Power Up Time 3 s Reset Time 4 6 s @24V, led off, no comm. Power Up urrent @ 24VD Supply 400 u dded, for 3s max (due to EEPROM read) Remote Output Voltage @ 24VD Supply 22.5 V Remote Output urrent @ 24VD Supply 10.8 m PW4 Stabilization Time 2 s Entering/Exiting Test Mode Sensor Update Frequency 5 4 6 s Photo chamber sampling time 10 of 27
DRIFT OMPENSTION ONSTNTS (PW1 = 300us) lean ir Value 480 Drift Limit 1120 80% Drift Limit (if function enabled) 992 Note: These constants are unprocessed raw chamber values available only from PW6/sub-address 1 when this feature is factory enabled. ll the limits are microseconds. ENVIRONMENTL SPEIFITIONS SPEIFITION TYP MIN MX UNITS OMMENTS Humidity 15 90 % RH Temperature -30 60 Limits imposed from wax melting ir Velocity Pressure N/ N/ SENSITIVITY SPEIFITIONS SPEIFITION PRINT REFERENE. Range OMMENTS Smoke limits S61-179-XX Photo Static temperature limits S61-105-XX Thermal TYPIL MESURBLE RNGE SPEIFITION RNGE UNITS OMMENTS IR limits 0-450 uw/cm² Irradiance on IR sensor 11 of 27
WVEFORM MENINGS 3 BIT DEFINITIONS SENSOR PW DEFINITIONS BIT 1 SENSOR/MODULE SELET PW1 REFERENE BITS 2 5 HIGH DDRESS ODE SWITH BITS PW2 REMOTE TEST STTUS BITS 6 9 LOW DDRESS ODE SWITH BITS PW3 MNUFTURER ODE BITS 10 12 ONTROL BITS PW4 SENSITIVITY BIT 13 EVEN PRITY BIT PW5 TYPE IDENTIFITION PW6 PW7 RW HMBER VLUE (IF ENBLED) HIGHEST TEMPERTURE VLUE (IF ENBLED) PW8 SET TO 0 3) See Figure 1 PW9 RW IR SENSOR VLUE (IF ENBLED) PW LIMITS (PW1 = 300 s) BSOLUTE LIMITS (due to environmental/aging effects) MIN TYP MX PW1 285 300 315 PW2 285 300 315 PW2 (RemoteTest) 570 600 630 PW2 (Level 6 enabled) 855 900 945 PW2 (Level 6 disabled) 1140 1200 1260 PW2(Separate remote output control disabled) 1425 1500 1575 12 of 27
PW2(Separate remote output control enabled) 1710 1800 1890 PW3 (OEM code 570 600 630 PW4 (Normal, clean) 760 800 840 PW4 (Low hamber Trouble / Thermistor trouble/ir self test failure/freeze alert ) 140 150 160 PW4 (Maintenance Urgent / Drift Limit) 285 300 315 PW4 (Maintenance lert: 80% drift limit OR continuous IR saturation condition) 425 450 475 PW4 (IR light saturation condition) 665 700 735 PW4 99% drift (80% drift limit disabled) 1140 1200 1260 PW4 (larm 1) 1%/ft no delays- 1330 1400 1470 PW4 (larm 2) 2%/ft no delays. 1710 1800 1890 PW4 (larm 3) 3 %/ft no delays. 2090 2200 2310 PW4 (larm 4) 3%/ft with 0 45 delay. 2470 2600 2730 PW4 (larm 5) 3%/ft with 1 30 delay. 2850 3000 3150 PW4 (larm 6 Heat / Magnet Test) * 3230 3400 3570 PW4 (Remote Test / Magnet Test) 2850 3000 3150 PW5 (Type ID) 2565 2700 2835 PW6 (Raw photo sensor value) 370 480 610 PW7 (Heat levels) @ 25-900 - PW9 (IR level) 0-4920 Note: ll the limits are microseconds * If level 6 is enabled If extended PWs are enabled. 13 of 27
REFERENE TBLE DRWING NO. S61-491-000 S61-432-000 S61-431-000 S00-003-xx 200 SERIES DVNED PROTOOL DESIGN GUIDE 500 SERIES PROTOOL DESIGN GUIDE ENHNED PROTOOL DESIGN GUIDE INTELLIGENT BSE PRODUT SPEIFITION 14 of 27
LRM TEST FETURES PPLIBLE TEST METHODS OMMENTS Test Magnet Panel Remote Test erosol Heat Gun MEHNIL SPEIFITIONS SPEIFITION TYP MIN MX UNITS OMMENTS Wire Gauge for Screw Terminals Maximum Terminal Screw Torque Refer to intelligent base product spec. S00-003-XX Refer to intelligent base product spec. S00-003-XX Height 68 mm when used with a B501 base Length or Diameter 102 mm Weight 124 g 15 of 27
FIG. 1 - SERIL OMMUNITION WVEFORM WITH QUNTITIES DEFINED Bit high Bit low Supply voltage 1 2 3 4 5 6 7 8 9 10 11 12 13 Data bit high Data bit low PW1 PW2 PW3 PW4 PW5 Bit interval Software Reset Time FIG. 2 - SERIL OMMUNITION WVEFORM DVNED PROTOOL 24V 5V 0V 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 H 3 H 2 H 1 H 0 L 3 L 2 L 1 L 0 G 7 G 6 G 5 G 4 G 3 G 2 G 1 G 0 P P E / K L R M S/W Reset M 7 M 6 M 5 M 4 M 3 M 2 M 1 M 0 P P E R R S/W Reset D B 7 D B 6 D B 5 D B 4 D B 3 D B 2 D B 1 D B 0 P P E R R S/W Reset M/S 1111.1100 / 1111.1011 Group ode/ddress Even Parity ommand DB7 to P will be held at 5V if devices are to respond Note: in group polling the parity error bit is not used in this version of product firmware 16 of 27
Io (m) If (m) I (m) t (μs) Transition Time FIG. 3-50 m OUTPUT DRIVER SIGNLLING WVEFORM FOR URRENT SINK 17 of 27
PW6 VS Light Transmission 200 180 160 140 120 100 usx16 min typ max 80 60 40 20 0 100 98 96 94 92 90 88 86 84 82 LT FIG. 4 - UNPROESSED PHOTO SENSOR VLUES 18 of 27
PWT=(T+87)X8 PW7(us) 1500 1400 1300 1200 1100 1000 900 800 700 600 500-20 -10 0 10 20 30 40 50 60 70 80 T( ) min typ max Fig. 5 - UNPROESSED THERML VLUE VS TEMPERTURE 19 of 27
Typical PW9 VS Irradiance us 5500 5000 4500 4000 3500 3000 2500 2000 1500 1000 500 0 0 100 200 300 400 500 600 Ie [uw/cm²] Ie typ Ie min Ie max Fig.6 UNPROESSED IR VLUES VS IRRDINE [uw/cm²] 20 of 27
EEPROM ONTENTS INFORMTION LOTION RED FTORY PROGRMMED VLUE Photo drift limit 10 Read 35 Photo factory clear air 12 Read Depends on calibration....... Firmware Revision 18 Read Revision number OEM Manufacturer ID 19 Read Depends on OEM Type ID 20 Read 32....... hecksum 31 N/ Depends on EEPROM contents Photo current average 32 Read Depends on calibration Environment application number 38 Read/Write 255 LED control group code 41 Read/Write 0 Remote output control group code 42 Read/Write 0 Remote Test group code 43 Read/Write 0 Thermal alarm group code 44 Read/Write 0 larm Latch Limit 1 (Processed sensor value) 49 Read/Write 255 larm Latch Limit 2 (Processed sensor value) 50 Read/Write 255 larm Latch Limit 3 (Processed sensor value) 51 Read/Write 255 larm Latch Limit 4 (Processed sensor value) 52 Read/Write 255 Fault latch limit 1 (Processed sensor value) 53 Read/Write 255 Fault latch limit 2 (Processed sensor value) 54 Read/Write 255 Fault latch limit 3 (Processed sensor value) 55 Read/Write 255 Fault latch limit 4 (Processed sensor value) 56 Read/Write 255 larm Latch Limit 1 (Sensing element photo) 57 Read/Write 255 larm Latch Limit 2 (Sensing element photo) 58 Read/Write 255 larm Latch Limit 3 (Sensing element photo) 59 Read/Write 255 larm Latch Limit 4 (Sensing element photo) 60 Read/Write 255 Fault latch limit 1 (Sensing element photo) 61 Read/Write 255 21 of 27
INFORMTION LOTION RED FTORY PROGRMMED VLUE Fault latch limit 2 (Sensing element photo) 62 Read/Write 255 Fault latch limit 3 (Sensing element photo) 63 Read/Write 255 Fault latch limit 4 (Sensing element photo) 64 Read/Write 255 larm Latch Limit 1 (Sensing element thermal #1) 65 Read/Write 255 larm Latch Limit 2 (Sensing element thermal #1) 66 Read/Write 255 larm Latch Limit 3 (Sensing element thermal #1) 67 Read/Write 255 larm Latch Limit 4 (Sensing element thermal #1) 68 Read/Write 255 Fault latch limit 1 (Sensing element thermal #1) 69 Read/Write 255 Fault latch limit 2 (Sensing element thermal #1) 70 Read/Write 255 Fault latch limit 3 (Sensing element thermal #1) 71 Read/Write 255 Fault latch limit 4 (Sensing element thermal #1) 72 Read/Write 255 larm Latch Limit 1 (Sensing element thermal #2) 73 Read/Write 255 larm Latch Limit 2 (Sensing element thermal #2) 74 Read/Write 255 larm Latch Limit 3 (Sensing element thermal #2) 75 Read/Write 255 larm Latch Limit 4 (Sensing element thermal #2) 76 Read/Write 255 Fault latch limit 1 (Sensing element thermal #2) 77 Read/Write 255 Fault latch limit 2 (Sensing element thermal #2) 78 Read/Write 255 Fault latch limit 3 (Sensing element thermal #2) 79 Read/Write 255 Fault latch limit 4 (Sensing element thermal #2) 80 Read/Write 255 larm Latch Limit 1 (Sensing element IR) 81 Read/Write 255 larm Latch Limit 2 (Sensing element IR) 82 Read/Write 255 larm Latch Limit 3 (Sensing element IR) 83 Read/Write 255 larm Latch Limit 4 (Sensing element IR) 84 Read/Write 255 Fault latch limit 1 (Sensing element IR) 85 Read/Write 255 Fault latch limit 2 (Sensing element IR) 86 Read/Write 255 Fault latch limit 3 (Sensing element IR) 87 Read/Write 255 Fault latch limit 4 (Sensing element IR) 88 Read/Write 255 22 of 27
INFORMTION LOTION RED FTORY PROGRMMED VLUE User data byte 1 97 Read/Write 0 User data byte 2 98 Read/Write 0 User data byte 3 99 Read/Write 0 User data byte 4 100 Read/Write 0 User date byte 5 101 Read/Write 0 23 of 27
SUB-DDRESS LOTIONS PROESSED SENSOR VLUES VLUE MENING DIRETION VLUE TYP 0 Processed value Input Low hamber Trouble / Thermistor trouble/ir self test failure/freeze alert 9 1 Photo sensor Input Maintenance Urgent / Drift Limit 19 2 Thermal 1 Input Maintenance lert: 80% drift limit OR continuous IR saturation condition 28 3 Thermal 2 Input IR light saturation condition 44 4 IR Input Normal, clean 50 129 LED control Output 99% of drift range 75 130 Remote output control Output larm 1 1%/ft 87 131 Remote Test Output larm 2 2%/ft 112 132 Thermal alarm Output larm 3 3%/ft 137 larm 4 3%/ft delay 162 Remote Test / Magnet Test 187 larm 5 3%/ft delay 187 larm 6 Heat (FT or ROR) 212 Maximum smoke value 212 Internal Fault 254 Power up special value 255 24 of 27
DIRET ND GROUP POLLING OMMNDS OMMND FUNTION DT/DIRETION DT SUBDDRESS ID DESRIPTION 1 Set Outputs 1 byte/panel to device (2x) 0 129 Turn alarm LED Off 1 129 Pulse alarm LED on communication (Blinking) 2 129 Turn alarm LED On 3 129 Intermittent alarm LED on 4 129 Pulse Green LED on communication (Blinking) 5 129 Turn Green LED On 6 129 Intermittent Green LED On (where Green LED fitted) 0 130 Turn remote output Off 1 130 Pulse remote output on communication (Blinking) 2 130 Turn remote output On 3 130 Intermittent remote output on 0 131 Turn Remote Test Off 2 131 Turn Remote Test On 0 132 No heat alarms 1 132 Enable rate of rise alarm 2 132 Enable fixed temperature alarm 3 132 Enable rate of rise and fixed temperature alarm 2 Read Output Status 1 byte/device to panel 0 129 larm LED Off 1 129 larm LED pulsing on communication (Blinking) 2 129 larm LED On 3 129 Intermittent alarm LED on 2 Read Output Status (continued) 1 byte/device to panel 4 129 Green LED pulsing on communication (Blinking) 25 of 27
OMMND FUNTION DT/DIRETION DT SUBDDRESS ID DESRIPTION 5 129 Green LED On 6 129 Intermittent Green LED On 129 (where Green LED not fitted) 0 130 Remote output Off 1 130 Remote output pulsing on communication (Blinking) 2 130 Remote output On 3 130 Intermittent remote output on 0 131 Remote Test Off 2 131 Remote Test On 0 132 No heat alarms 1 132 Rate of rise alarm enabled 2 132 Fixed temperature alarm enabled 3 132 Enable rate of rise and fixed temperature alarm 3 Load Group ode 1 byte/panel to device (2x) 0 255 129-132 (output) Set by panel, EEPROM value on Power On Reset 4 Reset larm Latch 1 byte/panel to device 0 255 0-5 Reset Interrupt Latch. 1 in the relevant bit position determines which interrupt to reset. 5 Read Group ode 1 byte/device to panel (Default = 0) 0 255 129-132 (output) Transmit Group ode to Panel 8 Read larm/fault Latch ondition Units 9 Read larm/fault Latch ondition Tens 10 Read Presence ondition 1 byte/panel to device 10 bits/device to panel 1 byte/panel to device 10 bits/device to panel 0 15 0 1023 NO Units with an interrupt corresponding to the tens address sink current in bits 0-9 (300 s defines fault, 600 s defines alarm) 2 bytes/device to panel 0 255 NO ll units with an interrupt sink current in the relevant bit equal to their tens address within the relevant response byte (300 s defines fault, 600 s defines alarm) 0 15 NO 0 1023 ll installed units with the corresponding tens address sink current in bits 0-9 in the relevant bit position. Note that on power on, there is no current sink until the Reset Power On 26 of 27
OMMND FUNTION DT/DIRETION DT SUBDDRESS ID DESRIPTION command has been issued or this command is received 5 times 11 Write larm Latch Register 2 bytes/panel to device 0 255 0-5 onfigure larm Latch Register (00 off, 01 = high, 02 = low, 03 = high/low) 12 Read larm Latch Register 2 bytes/device to panel 0 255 0-5 Transmit larm Latch Register to Panel (Default = 0) 13 Read Sensor value 1 byte/device to panel 0 255 0-5 Transmit Sensing Element Raw Value. Note that on power on, the processed value is 255 until the Reset Power On command has been issued. 14 Read Multiple Device Input value 15 Read ddress using Serial Number 16 Read Serial Number using ddress 17 Disable nswer using Serial Number 18 Read EEPROM Data 3 bytes/panel to device N bytes/device to panel 19 Write EEPROM Data 3 bytes/panel to device N bytes/panel to device 5 bytes/device to panel 0 255 NO Transmit subsequently the processed and raw sensor values. Note that on power on, the processed value is 255 until the Reset Power On command has been issued. 4 bytes/panel to device $00.00.00.00 $FF.FF.FF.FF NO Transmit ddress of factory programmed Serial Number 1 byte/device to panel 0 159 1 byte/panel to device 0 159 NO Transmit factory programmed Serial Number for device 4 bytes/device to panel $00.00.00.00 $FF.FF.FF.FF addressed. 4 bytes/panel to device $00.00.00.00 $FF.FF.FF.FF NO Disable any answer of factory programmed Serial Number, to Read Serial Number using ddress command. Location: 0 65534 Length: 1 128 Data: 0 255 Location: 0 65534 Length: 1 128 Data: 0 255 NO NO Transmit contents of specified EEPROM locations Rewrite specified EEPROM locations by transmitted bytes in sequence starting at first location specified. 21 Reset Power On no data NO lear special value 255 given at power up 22 Read/Write EEPROM Result 1 byte/device to panel 0 1 NO Transmit result of last Read/Write EEPROM Data command 23 Reset Device no data NO Re-Write whole EEPROM to default values and initialize RM variables 27 of 27