A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator Features and Benefits Description Low average standby current allows 10-year battery life 2.3 to 5.5 V operating range Interconnect option Logic outputs to control an external sound IC Low battery detection and warning Chamber sensitivity test and warning Triple horn-chirp to distinguish chamber warning Power-on reset (POR) Digital filter on I/O provides significant noise immunity Timer (hush) mode for enabling reduced sensitivity period Built-in circuits to reduce false triggering ESD protection circuitry on all pins Temporal Horn Pattern, per UL217, NFPA72, ISO8201 Latching alarm indicator identifies alarm-initiating devices The A5303 is a low-current BiCMOS photoelectric smoke detector circuit with ultra-low standby current and can operate for 10 years powered by inexpensive batteries. This device can be used with an infrared optical chamber to sense light scattered from smoke particles. A networking capability allows units to be interconnected so that if any unit senses smoke all units will sound an alarm. Special features are incorporated in the design to facilitate calibration and testing of the finished detector. Package: 20-pin TSSOP (suffix LE) A variable-gain photoamplifier can be directly interfaced to an infrared emitter-detector pair. The amplifier gain levels are determined by two external capacitors and are internally selected depending on the operating mode. Low gain is selected during standby and timer modes. During a local alarm, this low gain is increased (internally) by approximately 45% to provide hysteresis. High gain is used during pushbutton test and to periodically monitor the chamber sensitivity during standby. The internal oscillator and timing circuitry minimize standby power by sensing for smoke for only 100 s once every 10 s. A special three-stage-speedup sensing scheme is incorporated to minimize the time to an audible alarm and also to reduce false triggering. Chamber sensitivity is periodically monitored and two consecutive cycles of degraded sensitivity are required for a warning signal to occur. The A5303 is supplied in a thin profile (<1.2 mm overall height) 20-pin TSSOP package (0.65 mm nominal lead pitch). The package is lead (Pb) free with 100% matte tin leadframe plating. Not to scale Typical Application Diagram To / from other units 56 nF 3 k VDD 5.6 nF Gain Select 560 Connect to allow timer (hush) mode operation 5 k 10 F A LVSET Low Batt C2 200 k Low Batt Sample Push-to-test TEST R2 Smoke Chamber VDD BLINK STROBE SOUT0 SOUT1 SOUT2 Voice IC outputs HORN Output to optional boost converter to drive a piezo horn VDD 1.6 V Control Logic IRED 100 F ISET LED 3 Red LED HUSH Connect HUSH to VSS to disable timer mode B DETECT 1 k OSC Timing VSS OSCCAP 1500 pf TRES 100 k 5303-DS 3V VDD 1.2 V VDD C1 R1 220 I/O VDD 10 A A resistor connected between this pin and VDD or VSS adjusts the low-battery threshold B In standby, BLINK = VDD causes LED to blink, BLINK = V SS causes LED not to blink Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator A5303 Selection Guide Part Number A5303SLE-T A5303SLETR-T Pb-free and RoHS Yes Yes Package 20-pin TSSOP (JEDEC MO-153AC) 20-pin TSSOP (JEDEC MO-153AC) Packing 75 pieces / tube 4000 pieces / reel Absolute Maximum Ratings Characteristic Symbol Notes Rating Units -2.3 to 6 V Supply Voltage Range VDD Referenced to VSS DC Input Voltage Range VIN Referenced to VSS -0.3 to 6 V Operating Ambient Temperature Range TA Allegro Range S -20 to 85 C TJ(max) 150 C Tstg -55 to 150 C Maximum Junction Temperature Storage Temperature Range Thermal Characteristics Characteristic Symbol Package Thermal Resistance RJA Test Conditions* Estimated, single-layer PCB, minimal exposed copper area Value Units 127 C/W *Additional thermal information available on Allegro website. Terminal List Pin-out Diagram SOUT1 1 20 SOUT2 SOUT0 2 19 LED I/O 3 18 HORN Number Name Function 1 SOUT1 Logic push-pull output for controlling an external sound IC 2 SOUT0 Logic push-pull output for controlling an external sound IC 3 I/O 4 BLINK Logic input for enabling/disabling the LED blink during standby Input-output to interconnected detectors 5 HUSH Input for photoamplifier timer mode reference; can also disable timer mode BLINK 4 17 TEST 6 ISET A resistor on this pin connected to VSS sets the IRED output current HUSH 5 16 OSC CAP 7 VDD Positive supply voltage ISET 6 15 VSS VDD 7 14 TRES 8 IRED Terminal to drive smoke chamber IR LED IRED 8 13 LVSET 9 STROBE Strobed supply (VDD - 2 V) for photoamplifier low-side reference STROBE 9 12 C1 10 DETECT DETECT 10 11 C2 11 C2 Sets photoamplifier gain in standby mode Photoamplifier input 12 C1 Sets photoamplifier gain in supervisory mode 13 LVSET Optionally used with a resistor to adjust the low-battery threshold 14 TRES Connection for resistor to set clock times/frequency 15 VSS 16 OSC CAP Negative supply voltage Connection for capacitor and resistor to set clock times/frequency 17 TEST Enables push-to-test mode; starts timer mode, if enabled 18 HORN Logic output which optionally enables a boost converter to drive a horn 19 LED 20 SOUT2 Output to drive visible LED Logic push-pull output for controlling an external sound IC Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 2 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator DC ELECTRICAL CHARACTERISTICS1 Valid at TA = 25C, VDD = 2.3 to 5.5 V, configured as in Typical Application Diagram (unless otherwise noted) Characteristics Symbol Test Conditions Min. Typ.2 Max. Unit 2.3 3.0 5.5 V Supply Voltage Range VDD Operating During standby, STROBE off - 2.3 5.0 A Operating Supply Current IDD During STROBE on, IRED off - 210 300 A During STROBE on, IRED on - 220 300 A -100 0 100 nA - 3.5 - A V Input Current TEST Pulldown Current IIN IIN(TEST) BLINK, C1, C2, DETECT, OSC CAP, TRES (pulldown off) VTEST = VDD = 3 V Logic Voltage Low VI(L) - - VDD x 0.3 Logic Voltage High VI(H) VDD x 0.7 - - V Strobe Output Voltage VST Inactive Line Regulation Strobe Temperature Coefficient Maximum IRED Current Setting - VDD - V VDD - 2.1 VDD - 2.0 VDD - 1.9 V - -60 - dB VSTROBE, VDD = 2.3 to 5.5 V - 0.01 - % / C Current is set by selection of resistor on ISET pin - - 300 mA 89 100 111 mA Active, IO = 100 to 500 A VST(VDD) Active, VDD = 2.3 to 5.5 V ST IIRED(MAX) IRED Current IIRED RISET = 3 IRED Temperature Coefficient IRED IIRED, VDD = 2.3 to 5.5 V - 0.40 - % / C ILED VLED = 0.5 V 0.6 1.2 1.8 mA Low-Battery Warning Threshold VDD(th) LVSET open 2.4 2.5 2.6 V Low-Battery Warning Minimum VDD(warn) VDD - 1.0 - VDD - 0.3 V LED Drive Current Common Mode Voltage VIC VDD voltage guaranteed to operate SOUTx pins Photoamplifier input 1.8 V Smoke Comparator Reference Voltage VREF Any alarm condition, except hush mode - VDD - 1.6 - V I/O Input Impedance ZI/O(in) No alarm conditions 40 83 - k I/O Output Impedance ZI/O(out) Local or test alarm - 3.9 5.7 k 1Limits over the operating temperature range are based on characterization data. Characteristics are production tested at 25C only. 2Typical values are at 25C and are given for circuit design information only. Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 3 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator AC ELECTRICAL CHARACTERISTICS1 Valid at TA = 25C, VDD = 2.3 to 5.5 V, configured as in Typical Application Diagram (unless otherwise noted) Characteristics Oscillator Period Smoke Check Low Battery Test Degraded Chamber Test LED Pulse Period Symbol Typ.2 Max. Unit 1 9.4 10.5 11.5 ms 210 9.6 10.75 11.9 s min tbattery No low-battery detected 218 41.3 45.9 50.5 tbattery2 Low-battery detected 212 39 43 48 s tchamber No degraded chamber detected 218 41.3 45.9 50.5 min tchamber2 Degraded chamber detected 212 39 43 48 s - No LED Pulses - - tled0 No local or remote smoke, BLINK = VSS - tled1 No local or remote smoke, BLINK = VDD 212 39 43 48 s tled3 Local smoke 48 0.45 0.50 0.55 s tled4 Remote smoke only - - No LED Pulses - - tled6 Pushbutton test, induced alarm 48 0.45 0.50 0.55 s tled7 Timer mode, no alarm 210 9.67 10.75 11.83 s 1 9.5 10.5 11.5 ms 3 pulses, degraded chamber 26 0.60 0.67 0.74 s tw(led) tsp(led) IRED Pulse Period Min. tosc LED Pulse Spacing STROBE Pulse Width OSC Count tsmoke LED Pulse Width STROBE Pulse Period Test Conditions tst1 No local or remote smoke 210 9.6 10.75 11.9 s tst2 After 1 of 3 valid samples 192 1.8 2.0 2.2 s tst3 After 2 of 3 valid samples and during local alarm 96 0.8 1.0 1.1 s tst4 Remote smoke only 768 7.2 8.0 8.9 s tst5 Chamber test, no local alarm 218 41.3 45.9 50.5 min tst6 Pushbutton test, induced alarm 24 225 252 278 ms tw(st) 1 9.5 10.5 11.5 ms tired1 No local or remote smoke 210 9.6 10.75 11.9 s tired2 After 1 of 3 valid samples 192 1.8 2.0 2.2 s tired3 After 2 of 3 valid samples and during local alarm 96 0.8 1.0 1.1 s tired4 Remote smoke only 768 7.2 8.0 8.9 s tired5 Chamber test, no local alarm 218 41.3 45.9 50.5 min tired6 Pushbutton test, induced alarm 24 225 252 278 ms IRED Pulse Width tw(ired) 0.01 94 105 116 s I/O to Active Delay td(io) Local alarm - - 0 - s I/O Charge Dump Duration tdump End of local alarm or test 96 0.9 1.0 1.1 s Rising Edge on I/O to Alarm tr(io) No local alarm 9 to 13 9x tosc 94.5 - 137 13 x tosc ms Continued on the next page... Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 4 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator AC ELECTRICAL CHARACTERISTICS (continued)1 Valid at TA = 25C, VDD = 2.3 to 5.5 V, configured as in Typical Application Diagram (unless otherwise noted) Characteristics SOUTx Output Warning Period Symbol Test Conditions OSC Count Min. Typ.2 Max. Unit tsoutx Low supply or degraded chamber 212 38.9 43 47.1 s tw(soutx) Low supply or degraded chamber 1 9.5 10.5 11.5 ms Horn Warning Pulse Period thorn Low battery or degraded chamber 212 38.9 43 47.1 s Horn Warning Pulse Width tw(horn) Low battery or degraded chamber 1 9.5 10.5 11.5 ms Horn Warning Pulse Spacing tsp(horn) 3 chirps, degraded chamber 26 0.60 0.67 0.74 s Horn On-Time ton(horn) Local, remote, or test alarm 48 450 500 550 ms toff1(horn) Local, remote, or test alarm (see Timing Diagrams section) 48 450 500 550 ms toff2(horn) Local, remote, or test alarm (see Timing Diagrams section) 144 1350 1500 1650 ms 57344 9.0 10.0 11.0 min 21.5 - 32.3 3072 x tosc s SOUTx Output Warning Pulse Width Horn Off-Time Timer Mode Duration Failed Push-Test Indication on SOUTx 1Limits ttimer tFAIL After TEST input goes low 211 to 3072 211 x tosc over the operating temperature range are based on characterization data. Characteristics are production tested at 25C only. values are at 25C and are given for circuit design information only. 2Typical Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 5 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator Pin and Circuit Description (In Typical Application) C1 Pin A capacitor connected to this pin determines the gain of the photoamplifier, Ae , during the push-to-test mode and during the chamber monitor test. A typical capacitor value for this highgain (supervisory) mode is 0.047 F, but it should be selected based on the photochamber background reflections reaching the detector and the required level of sensitivity. Ae = 1 + (C1 / 12), where C1 is in pF. Ae should not exceed 10,000 and thus C1 should not exceed 0.1 F. Coupling of other signals to the C1, C2, and DETECT inputs must be minimized. C2 Pin A capacitor connected to this pin determines the gain of the photoamplifier, Ae, during standby. A typical capacitor value for this low-gain mode is 4700 pF, but it should be selected based on a specific photochamber and the desired level of sensitivity to smoke. Ae = 1 + (C2 / 12), where C2 is in pF. Ae should not exceed 10,000 and thus C2 should not exceed 0.1 F. This gain increases by a nominal 45% after a local alarm is detected (three consecutive detections). A resistor must be installed in series with the C2 capacitor. DETECT Pin This is the input to the photoamplifier and is connected to the cathode of the photodiode. The photodiode is operated at zero bias and should have low dark leakage current and low capacitance. A shunt resistor must be installed in parallel with the photodiode. STROBE Pin This output provides a strobed, regulated voltage of VDD - 2 V. The minus side of all internal and external photoamplifier circuitry is referenced to this pin. VDD Pin This pin is connected to the positive supply potential, typically 3 V. LVSET Pin This pin allows the user to externally adjust the low-battery alarm threshold. To increase the threshold, a resistor can be connected between LVSET and VDD. To decrease the threshold, a resistor can be connected between LVSET and VSS. IRED Pin This output provides a pulsed drive current for the external IR emitter. To minimize noise impact, the IRED is not active when the visible LED output is active. ISET Pin This pin allows the user to externally set the IRED current by connecting a resistor between it and VSS. The IRED current controls the amount of light generated by the IR LED in the chamber. The IRED current, in mA, can be approximated using the following equation: IIRED (mA) = 300 / RISET (1) The chosen resistor should set a maximum of 300 mA (typically a minimum of 1). I/O Pin A connection at this pin allows multiple smoke detectors to be interconnected. If any single unit detects smoke, its I/O pin is driven high, and all connected units will sound their associated alarm indicators. As an input, this pin is sampled every 4 clock cycles (nominally 43 ms) during standby, and two consecutive samples and one additional clock with I/O high are required before signaling an alarm. If the I/O line goes low at all during the 96.8 ms, the remote alarm is not enabled, providing significant immunity to I/O noise and other pulses on the I/O line which are shorter than 9 clock cycles. The LED is suppressed when an alarm is signaled from an interconnected unit, and any local-alarm condition causes this pin to be ignored as an input. An internal NMOS device acts as a charge dump to aid in applications involving a large (distributed) capacitance, and is activated at the end of a local or test alarm. This pin has an on-chip pull-down device and must be left unconnected if not used. In the application, there should be a series current-limiting resistor to other smoke alarms. SOUT0, SOUT1, SOUT2 Pins These pins provide push-pull CMOS logic outputs to control an external sound IC. The outputs indicate the state of the device as follows: Condition Standby Local Alarm Remote Alarm Push-Test Passed Push-Test Failed Low-Battery Degraded Chamber SOUT2 L L L L H H H SOUT1 L L H H L L H SOUT0 L H L H L H L Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 6 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator A5303 HORN Pin The HORN pin is a logic output provided to enable an optional, external boost converter that can drive a piezoelectric (piezo) horn. Using a boost converter to drive a piezo horn allows alarms to generate high SPL levels from low supply voltages. HORN will be driven high to enable the boost converter. The output of the boost converter will be connected to the piezo horn such that the horn will sound when the converter is enabled. If a boost converter and horn are not used, this pin should be left open. BLINK Pin This logic input determines the LED operation while the device is in standby. If BLINK is connected to VDD the device will blink once every approximately 43 s in standby. If BLINK is connected to VSS the device will not blink in standby. If a low-battery or degraded-chamber condition exists while the device is in standby, the LED will blink as described in the Alarm Indications section, regardless of the state of the BLINK pin. The BLINK pin has no effect when the device is in local, remote, or test alarm. LED Pin This open-drain NMOS output is used to directly drive a visible LED. The LED indicates detector status as follows (with component values as in the typical application, all times nominal): nominally 105 s. The internal clock high time can be calculated by: Thigh = 0.693 x RTRES x COSCCAP (3) VSS Pin This pin is connected to the negative supply potential (usually ground). HUSH Pin This input pin serves two purposes in standby mode. It serves to enable/disable entering the internal 10-minute (nominal) "hush" timer mode, and also as the reference for the smoke comparator during timer mode. Timer mode allows the user to temporarily hush alarms caused by nuisance smoke or steam (such as from cooking). When the voltage on this pin is greater than approximately 50 mV, entering timer mode is enabled, and a high-to-low transition on the TEST pin resets and starts timer mode. If use of timer mode is not desired this pin must be connected to VSS, and timer mode is disabled. OSC CAP (Oscillator Capacitor) Pin During timer mode the smoke comparator reference is established externally by a resistive divider (R1 and R2) between VDD and STROBE. Also, during timer mode the photoamplifier gain, Ae, is internally reduced to about 55% that during the normal-gain mode. Thus, Ae = 1 + (C2 / 22), where C2 is in pF. These two conditions allow the detector to operate with reduced sensitivity during timer mode. If the level of smoke increases such that the temporary alarm threshold is reached, a local alarm will sound. If the HUSH pin is connected directly to STROBE without using a resistor divider, then a local alarm will never occur during timer mode, regardless of the smoke level. When not in timer mode, the smoke comparator reference is set internally to approximately VDD - 1.6 V. A capacitor between this pin and VDD, along with a parallel resistor, forms part of a two-terminal oscillator and sets the internal clock low time. With component values shown, this nominal time is 10.4 ms and essentially the oscillator period, which is also the STROBE pulse width. The internal clock low time can be calculated by: The resistor dividers formed by the adjustable photoamp-divider and the HUSH divider (R1 + R2, if timer mode is used) should be chosen so that the load on STROBE does not exceed 500 A. Thus, the photoamp-divider (8 k in the typical application) in parallel with the HUSH divider (R1 + R2) shall be no less than 4 k. Condition Pulse Occurrence Standby, BLINK = VDD Every 43.0 s Standby, BLINK = VSS No LED pulses Local Smoke Every 0.5 s Remote Alarm No pulses Test Mode Every 0.5 s Timer (Hush) Mode Every 10.8 s TEST Pin This pin has an internal pulldown device and is used to manually invoke push-to-test mode and timer mode. Push-to-test mode is TRES (Timing Resistor) Pin A resistor between this pin and OSC CAP is part of the two-termi- initiated by a voltage greater than approximately VDD - 0.5 V on this pin (usually the closure of a normally open push-button nal oscillator and sets the internal clock high time, which is also the IRED pulse width. With component values shown, this time is switch to VDD). After one oscillator cycle, the amplifier gain is Tlow = 0.693 x ROSCCAP x COSCCAP (2) Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 7 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator increased by internal selection of C1 so that background reflections in the smoke chamber can be used to simulate a smoke condition, and IRED pulses every 252 ms (nominal). After the third IRED pulse (three consecutive simulated smoke conditions), the successful test signals a continuous passing-test-alarm condition to the sound IC, outputs the temporal pattern to the piezo horn, and activates the I/O pin. When the pushbutton is released, the input returns to VSS due to the internal pulldown. After one oscillator cycle, the amplifier gain returns to normal, and after three additional IRED pulses (less than one second), the device exits this mode and returns to standby. This high-to-low transition on TEST also resets and starts the 10-minute (nominal) "hush" timer mode, if the mode is enabled via the HUSH pin. The high-to-low transition also resets the latching alarm indicator, if it is latched. If the chamber malfunctions or is too dirty, the push-test will fail to simulate a smoke condition, and after three failed STROBE pulses the device signals a continuous failing-test-alarm condition on the SOUTx pins. The piezo driver and the I/O pins are not enabled. Diagnostic Test/Calibration mode is available to facilitate calibration and test of the IC and the assembled detector. It is initiated by pulling TEST below VSS by continuously drawing 200 A from the pin for at least one clock cycle on OSC CAP. The current should not exceed 500 A and under these conditions, TEST pin voltage will clamp at approximately 250 mV below VSS. One option is to connect TEST to a -5 V supply through a 15 k resistor. In this mode, certain device pins are reconfigured as described in table 1. The IRED pulse rate is increased to one pulse every OSC CAP cycle and the STROBE pin is always active. To exit this mode, the TEST pin should be floated, or returned to VSS, for at least one OSC CAP cycle. Latching Alarm Indicator When multiple smoke detectors are networked through the I/O line, the latching alarm indicator allows the user to identify which detector(s) initiated an alarm. When a local alarm condition occurs, the initiating detector(s) will latch the event in memory. After the alarm condition has expired (the device stops signaling the alarm condition to the sound IC) the initiating detector(s) will output an additional 10 ms LED pulse every 43 seconds. If the BLINK pin is connected to VDD, the additional pulse will occur 0.67 seconds after the normal standby pulse. The user can clear the latched alarm condition by pressing and releasing the push-totest button. If the user does not press the push-to-test button, the latched alarm condition will cease after 24 hours to preserve battery life, and to prevent masking future latched alarm indications. Alarm Indications Alarm conditions include: local smoke detection, a remote alarm, low battery, and degraded chamber sensitivity. These are indicated by a combination of SOUTx output, piezo horn, and LED signals, which continue until the alarm condition is resolved. A local alarm always overrides a remote alarm and a push-test. Remote alarm always overrides a push-test. A local alarm, remote alarm, or a push-test will inhibit warning signals for low battery or degraded chamber. During a local or a remote alarm condition, the device continuously signals an alarm condition on the SOUTx pins that indicates the type of the alarm. The piezo horn output is a continuous modulated tone (temporal horn pattern), nominally: 0.5 s on, 0.5 s off, 0.5 s on, 0.5 s off, 0.5 s on, and 1.5 s off. The visible LED also distinguishes a local alarm from a remote alarm. During a Table 1. Alternate Pin Configuration During Diagnostic Test/Calibration Mode Pin Name Alternate Configuration I/O Disabled as an output. A logic high on this pin places the photoamplifier output on the BLINK pin. The amplifier output appears as pulses. HUSH If the I/O pin is high, this pin controls the amplifier gain capacitor. If this pin is low, normal gain is selected. If this pin is high, supervisory gain is selected. NOTE: If I/O is low, clocking this pin will cause the device to exit diagnostic/calibration mode and enter an Allegro-defined test mode. BLINK If the I/O pin is high, this pin is reconfigured as the photoamplifier output. SOUT0 If the I/O pin is high and the HUSH pin is low (normal gain), taking this pin to a high logic level increases the amplifier gain by 45% (hysteresis). SOUT2 This pin is reconfigured as the smoke integrator output. Three consecutive smoke detections will cause this pin to go high and three consecutive no-smoke detections cause this pin to go low. LED This pin becomes a low-battery indicator. The opendrain NMOS output is normally off. If VDD falls below the low-battery threshold, the output turns on. OSC CAP This pin may be driven by an external clock source. Driving this pin low and high drives the internal clock low and high. The external RC network may remain intact. Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 8 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator local alarm, the LED blinks every 0.5 s (nominally), but during a remote alarm, the LED is disabled and does not blink. cleared or cleaned, and the test period then reverts to (nominally) 45.9 min. The degraded-chamber test occurs periodically (nominally every 45.9 min). During this test, the gain of the photoamplifier is switched to the high (supervisory) level, set by C1. The device expects that the photodiode will receive enough background reflections in the chamber to cause an alarm condition. If a faulty, dirty, or obstructed chamber prevents this during a test, the test period decreases to 43 s. After two consecutive failed tests, the device signals a degraded chamber condition to the sound IC. It also chirps the horn and pulses the LED three times every 43 seconds. The condition is resolved when the chamber is either The low-battery test also occurs periodically (also nominally every 45.9 min, but at a different time than the degraded-chamber test). During this test a resistive divider off VDD is compared to an internal band-gap reference. If VDD is below the threshold, the device signals a low battery condition to the sound IC and the test period decreases to 43 s. It also chirps the horn and pulses the LED once every 43 seconds. The condition is resolved when the battery is replaced and the test period then reverts to (nominally) 45.9 min. Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 9 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator Timing Diagrams (Not to Scale) Standby Mode OSC CAP tw(ired) Test event Internal clock tosc tbattery, tled0, tst5, tired5 tsmoke, tst1, tired1 Photo sample Low-battery test Chamber test tw(st) tchamber, tst5, tired5 STROBE IRED tled1 tw(led) LED, BLINK = VDD LED, BLINK = VSS (LED OFF) Low Battery Condition VDD (Low battery) tbattery tbattery2 tbattery2 tbattery Low-battery test tsoutx SOUTx tw(soutx) SOUT(2:0) = (HLH) thorn tw(horn) HORN tled1 tw(horn) LED these two pulses will not exist if BLINK = VSS Degraded Chamber Condition Chamber sensitivity Chamber test (Degraded chamber) tchamber tchamber2 tchamber2 tsoutx SOUTx tchamber tw(soutx) SOUT(2:0) = (HHL) thorn tw(horn) HORN tsp(led) tsp(horn) LED tw(led) Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 10 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator A5303 Local Smoke Detection Condition Chamber (smoke present) 1st strobe with smoke 3rd strobe with smoke 3rd strobe without smoke IRED tst2,ired2 tw(st) tst3,ired3 STROBE tw(led) LED tled3 tst3,ired3 BLINK = VSS or VDD SOUTx SOUT(2:0) = (LLH) ton(horn) toff2(horn) toff1(horn) HORN tdump I/O (OUTPUT) I/O charge dump Remote Alarm Condition LED BLINK = VSS or VDD (LED OFF) tw(st) tst4,ired4 STROBE SOUTx SOUT(2:0) = (LHL) ton(horn) toff2(horn) toff1(horn) HORN tr(io) I/O (INPUT) Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 11 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator A5303 Test Alarm Mode (passing) LED BLINK = VSS or VDD tw(led) tled6 STROBE tw(st) tst6,ired6 TEST SOUTx SOUT(2:0) = (LHH) ton(horn) toff2(horn) toff1(horn) HORN tdump I/O (OUTPUT) I/O charge dump Test Alarm Mode (failing) LED BLINK = VSS or VDD tw(led) tw(st) STROBE TEST SOUTx SOUT(2:0) = (HLL) tFAIL HORN I/O Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 12 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator A5303 Package LE, 20-Pin TSSOP 0.45 6.500.10 8 0 20 20 0.20 0.09 4.400.10 0.65 1.70 6.10 6.400.20 0.60 0.15 A 1 1.00 REF 2 0.25 BSC 20X SEATING PLANE 0.10 C 0.30 0.19 1.20 MAX 0.65 BSC 0.15 0.00 C 1 2 SEATING PLANE GAUGE PLANE B PCB Layout Reference View For Reference Only; not for tooling use (reference MO-153 AC) Dimensions in millimeters Dimensions exclusive of mold flash, gate burrs, and dambar protrusions Exact case and lead configuration at supplier discretion within limits shown A Terminal #1 mark area B Reference land pattern layout (reference IPC7351 SOP65P640X110-21M); All pads a minimum of 0.20 mm from all adjacent pads; adjust as necessary to meet application process requirements and PCB layout tolerances; when mounting on a multilayer PCB, thermal vias at the exposed thermal pad land can improve thermal dissipation (reference EIA/JEDEC Standard JESD51-5) Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 13 A5303 Photoelectric Smoke Detector with Interconnect, Timer, and Latching Alarm Indicator Allegro MicroSystems offers an industry-leading range of ionization and photoelectric smoke detector ICs. For a current listing, please visit our website at: www.allegromicro.com Copyright (c)2001-2010, Allegro MicroSystems, Inc. The products described herein are manufactured under one or more of the following U.S. patents: 5,045,920; 5,264,783; 5,442,283; 5,389,889; 5,581,179; 5,517,112; 5,619,137; 5,621,319; 5,650,719; 5,686,894; 5,694,038; 5,729,130; 5,917,320; and other patents pending. Allegro MicroSystems, Inc. reserves the right to make, from time to time, such departures from the detail specifications as may be required to permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that the information being relied upon is current. Allegro's products are not to be used in life support devices or systems, if a failure of an Allegro product can reasonably be expected to cause the failure of that life support device or system, or to affect the safety or effectiveness of that device or system. The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, Inc. assumes no responsibility for its use; nor for any infringement of patents or other rights of third parties which may result from its use. For the latest version of this document, visit our website: www.allegromicro.com Allegro MicroSystems, Inc. 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 14