L484 ® MAGNETIC PICKUP IGNITION CONTROLLER . . .. .. . . . DIRECT DRIVING OF THE EXTERNAL DARLINGTON OPERATES WITH A WIDE RANGE OF MAGNETIC PICKUP TYPES CHARGING ANGLE (DWELL) CONTROL COIL CURRENT PEAK LIMITATION CONTINUOUS COIL CURRENT PROTECTION TACHOMETER SIGNAL OUTPUT EXTERNAL DARLINGTON OVERVOLTAGE PROTECTION LOAD DUMP AND REVERSE BATTERY PROTECTION POSSIBILITY OF SPARK POINT DELAYING (ANTI KNOCK SYSTEM) DESCRIPTION The L484 is an integrated circuit designed for use with an NPN darlington in breakerless ignition systems with magnetic pickup sensors and high energy ignition coils. A key feature of the L484 is flexibility. It can be used with a wide variety of magnetic sensors thanks to the special design which has two input pins from the pickup ; the first is the zero crossing detector for the ignition command and the second pin is used to calculate the dwell time. Moreover another pin is used to adapt the L484 to various pickup types. Other features of the device include darlington overvoltage protection, dump protection, a supply voltage range of 6-28 V. DIP16 SO16 ORDERING NUMBERS : L484 (DIP16) L484D1 (SO16) BLOCK DIAGRAM September 2003 1/11 L484 ABSOLUTE MAXIMUM RATINGS Parameter Symbol VR VD Ptot Tj, Tstg Reverse Battery Voltage Dump Voltage Power Dissipation at Tamb = 90°C Junction and Storage Temperature Range Value Unit – 14 100 V V 0.75 W – 55 to 150 °C PIN CONNECTION THERMAL DATA Symbol Rth j-amb Value Unit Thermal Resistance Junction-ambient (DIP16) Max 80 °C/W Rth j-al Thermal Resistance Junction-alumina (SO16) Max 50 °C/W 2/11 Parameter L484 PIN FUNCTIONS (refer to fig. 2) N° 1 2 3 4 Name Function CURRENT SENSING INPUT Connection for Coil Current Limitation. The current is measured on the sense resistor RSENS and divided on R1/R2. The current limitation value is given by : R1 + R2 ISENS = RSENS R2 PICKUP INPUT Magnetic Pickup Signal Input. This pin sets the dwell time, i.e. the max negative pickup voltage value starting from which the device can drive the current into the coil. The real dwell time will be a function of the dwell control logic. Increasing the resistor R11 the maximum conduction time increases. The max input current foreseen is 2mA. A capacitor C1 connected between this pin and ground sets the delay of the PERMANENT permanent conduction protection in the coil current. Using a 50nF capacitor CONDUCT. PROTECTION TIMER the typical desaturation time delay for the protection is 75ms. PERMANENT CONDUCT. A low level on this input (max 0.7V) disables the protection, irrespective of PROTECTION INHIBIT the state of pin 3. If the protection is used this pin must be left open. 5 RPM OUTPUT Open collector output signal which is at a low level when the final darlington is in ON status. The current is internally limited at 10mA. 6 DWELL TIME ADJUST 7 DWELL CONTROL TIMER At high motor rotation speeds, i.e. when the peak value of the magnetic pick-up signal exceedes 6V using R12 = 100KΩ, this pin may be used to vary the dwell ratio. Adding a resistor in series Ra between this pin and pin 11 the desaturation time is reduced. It is therefore possible to use this pin to adapt the L484 to various pickup types. The maximum value of the resistor Ra is 200KΩ. A capacitor C2 connected between this pin and ground sets the timing for the dwell control. The recommended value is 100nF. The resistors R b/Rc provide an hysteresis to confirm ON state and avoid spurious sparks. 8 ZERO CROSSING INPUT 9 POWER-ON INPUT 10 SIGNAL GROUND 11 POWER SUPPLY 12 DUMP PROTECTION Zero cross detector input of the magnetic pickup signal for the ignition actuation. At high motor rotation speeds, the external resistor R12 may be used to vary the desaturation time ratio, to adapt the L484 to various signal waveforms of time magnetic pick-up. Reducing the resistor value the dwell time increases. Typically the range of values for resistor R12 is from 50KΩ to 150KΩ.. A low level on this pin forces the external darlington into conduction particularly useful in anti knock system. This function is particularly useful in antiknock system because provides a spark time delay. Anyway the current limitation, the permanent conduction protection and the dump protection are operating even when pin 9 is at a low level. If this function is not used it must be left open. This pin must be connected to ground. Supply Voltage Input. A 7V (typ) zener is present at the input. The external resistor R9 limits the current through the zener for higher supply voltages. The device is protected against the load dump. In load dump condition an internal circuit, based on a zener diode and a darlington transistor, switches off the external darlington and short circuits the supply. By means of the external divider R8/R9 the protection threshold can be changed and is given as first approximation by: R8 + R9 −4 VDth = 8.5 + 5 ⋅ 10 R8 R9 (the resistor R9 value must be higher than 4KΩ). * this function is particularly useful in antiknock systeme because provides a spark time delay. anyway the current limitation, the pemanent con duction protection and the dump protection are operating even when pin 9 is at a low level. 3/11 L484 PIN FUNCTIONS (continued) N° 14 15 Name Function DRIVER COLLECTOR INPUT The collector current for the internal driver which drives the external darlington is supplied through this pin. The external resistor R10 limits the dissipation in the IC. The value this resistor depends on the darlington used and on the limiting current in the coil. The external darlington is protected against overvoltage by means of an internal zener available at this pin. The external divider R5/R6 defines the limitation value, typically given by : OVERVOLTAGE LIMITATION 30 Vovp = + 5 ⋅ 10−3 ⋅ R6 + 30 R5 16 DRIVING STAGE OUTPUT Current Driver for the External Darlington. To ensure stability on the current limitation loop a capacitor C3 (typically 2.2nF, this value depending on the darlington used) must be connected between this pin and the current sensing input (pin 1). ELECTRICAL CHARACTERISTICS (VS = 14.4V ; TJ = - 40 to 125°C unless otherwise specified ; referred to the test circuit) Symbol VS VIS VTH VSENS Parameter Min. Typ. 6 Input Stage Voltage (pin 2 with 10KΩ resistor) On Pick-up Thresh. Voltage at LOW RPM (pin 2) 160 200 VIS–30 Unit 28 V 240 mV VIS+30 mV 320 60 200 3 mV mV mV 30 µA VS = 6 to 16V CD WELL Charge Current at LOW RPM CD WELL Discharge Current Vpick-up = 0.5V ; or pin 6 not connected (*) Note 1 7 7 15 I7C CD WELL Charge Current at HIGH RPM 8 33 µA I7D CD WELL Discharge Current Vpick-up = 9V 13 44 µA (**) Note 2 0.7 3.2 Vpin3 I3 Threshold Voltage Output Current Tamb = 25°C (***) Note 3 0.85 4 3 V µA VCp Continuous Coil Current Protection Inhibit LOW Voltage (pin 4). 0 0.7 V 1 0.6 V V 8.8 35 V V 3 0.7 mA V 10 µA I7D I7D/I7C I7D/I7C VCEsat VZ VOVZ I09 VCH ICH Series Darlington Driver Saturation Voltage (Vpin 14 - 16) 200 3 100 0.7 Max. Current Limitation Sensing Voltage (pin 1) Zero Crossing Thresh. Voltage (pin 8) Hysteresis Voltage (pin 8) VZC VH I7C 4/11 Test Conditions Operating Supply Voltage Ipin14 = 150mA Ipin14 = 50mA Zener Volt. Pin 11 Ipin11 = 140mA External Darlington Overvoltage Protection Tamb = 25°C ; Zener Voltage Ipin15 = 5 to 15mA Pin 9 Output Current in Low Status V9 = 0V Tachometer Signal Output LOW Voltage. ON Condition (pin5) Isink = 0.5mA Output Leakage (pin 5) OFF Condition Vpin5 = 5V 20 0.4 6.5 25 µA L484 DUMP PROTECTION Paramater Symbol Zener Dump (pin 12) VDZ Test Conditions Ipin12 = 2mA Min. 7.5 Typ. Max. Unit 9.5 V (*) Note 1 : TD/T is given by the formula : TD 1 = T 1 + I7D/I7C (**) Note 2 : TD T K = 1 + I7D/I7C K value depends on the pick–up used in the application ; typically K = 0.1 (***) Note 3 : the permanent conduction protection is guaranteed over the full temperature range CIRCUIT OPERATION The L484 controls the charging angle (dwell) and the peak value of the primary current in the coil over the full range of operating conditions. The coil current is limited to a predetermined level by means of a negative feedback circuit including a current sensing resistor, a comparator, the driver stage and the power switch. The dwell control circuit keeps the output stage in its active region during current limitation. The time the output stage is operating in the active region (desaturation time), is sufficient to compensate for possible variation in the energy stored due to the acceleration of the motor ; moreover this time is limited to avoid excessive power dissipation. MAGNETIC PICK–UP CHARACTERISTICS The typical magnetic pickup waveforms are shown in fig. 1, the amplitude of the signal being a function of the frequency. However on the market there are many types of magnetic pickup, of which the waveforms may differ very much. Adjusting the value of the resistor R11 on pin 2 and/or adding a resistor Ra between the pin 6 (dwell adjust) and pin 11, as shown in the application circuit, it is possible to adapt the L484 to a wide range of magnetic pickup waveforms. Particularly by means of the resistor R11 on pin 2 it is possible to define the maximum advance of the conduction start into the coil . This is very useful at high pick–up frequency. CONTROL OF THE DWELL ANGLE The dwell angle control circuit defines the conduction time of the output darlington, versus the speed of rotation, the supply voltage and the characteristics of the coil. In each cycle the time the transistor operates in the active region is compared with a reference time and the error signal amplified to advance or delay the conduction in the next cycle. To limit the power dissipation the desaturation time is typically fixed to 10% of the period T. At very low frequencies the ON thershold is fixed at 200mV of the input signal and the desaturation time is mainly determined by the peak waveform. This positive threshold also prevents permanent conduction when the motor is stopped. When the input frequency increases the dwell control gradually sets the desaturation time to 10% of the period. At higher frequencies the ON threshold becomes negative to permit a conduction angle of more than 50% always keeping desaturation time to 10% of the period. CURRENT LIMITING The current in the coil is measured by means of a voltage drop across a suitable resistor in the emitter lead of the power transistor. When the threshold voltage (260mV typ) is reached, the coil current is kept constant via a feedback loop. 5/11 L484 DARLINGTON OVERVOLTAGE LIMITATION The darlington is protected against overvoltage by means of an external divider R5 /R6 (pin 15) and an internal zener. This zener drives the external darlington in order to limit the collector voltage. CHARGING ANGLE SIGNAL OUTPUT This signal is intended for tachometer applications (pin 5). It consists of an open collector stage with current internally limited at 10mA "POWER ON" SIGNAL INPUT In the low status this input forces the external darlington into conduction (pin 9). This control input can be used together with the conduction time information coming from pin 5 to bypass the normal dwell time calculation. When an external logic control is used to recognize particular engine condition (as in anti Knock system). PROTECTION CIRCUITS PERMANENT CONDUCTION PROTECTION This function is intended to prevent continuous current conduction in the final stage when the magnetic pickup is open or intermittent. The duration of the intervention is set by means of a capacitor 1 at pin 3. Grounding pins 3 or 4, this protection is eliminated. The inhibit function at pin 4 is particularly useful when an external logic control is used to disable the permanent conduction protection. REVERSE BATTERY AND DUMP PROTECTION Due to the external resistors R6, R7, R8, R10 the device is protected against reverse battery. The load dump protection withstands up to 100V with a decay time ≤ 300ms. The intervention threshold for load dump is fixed by means of an external divider connected to pin 11. OTHER APPLICATION INFORMATION If the supply is voltage disconnected - or the battery wire is broken - while the current is flowing through the coil, the external diode D1 keeps the coil current from recirculating into the device : in this way both device and darlington are protected. The zener diode Dz, connected between pin 14 and GND, allows to withstand positive spikes up to 200V. The device - used in the recommended application circuit - satisfies the ISO/DP 7637/1 overvoltage standard. Figure 1 : Typical Magnetic Pick–up Waveform and L484 Response at low and high fequency. 6/11 L484 Figure 1 : Typical Magnetic Pick-up Waveform and L484 Response at Low and High Frequency (continued). 7/11 L484 Figure 2 : Application Circuit. 8/11 L484 mm DIM. MIN. a1 0.51 B 0.77 TYP. inch MAX. MIN. TYP. MAX. 0.020 1.65 0.030 0.065 b 0.5 0.020 b1 0.25 0.010 D 20 0.787 E 8.5 0.335 e 2.54 0.100 e3 17.78 0.700 F 7.1 0.280 I 5.1 0.201 L OUTLINE AND MECHANICAL DATA 3.3 0.130 DIP16 Z 1.27 0.050 9/11 L484 mm DIM. MIN. TYP. A a1 inch MAX. MIN. TYP. 1.75 0.1 0.25 a2 MAX. 0.069 0.004 0.009 1.6 0.063 b 0.35 0.46 0.014 0.018 b1 0.19 0.25 0.007 0.010 C 0.5 c1 45˚ (typ.) 9.8 10 0.386 0.394 E 5.8 6.2 0.228 0.244 e 1.27 0.050 e3 8.89 0.350 F (1) 3.8 4 0.150 0.157 G 4.6 5.3 0.181 0.209 L 0.4 1.27 0.016 0.050 S Weight: 0.20gr 0.020 D (1) M OUTLINE AND MECHANICAL DATA 0.62 0.024 SO16 Narrow 8˚(max.) (1) D and F do not include mold flash or protrusions. Mold flash or potrusions shall not exceed 0.15mm (.006inch). 0016020 10/11 L484 Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics. The ST logo is a registered trademark of STMicroelectronics. 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