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Freescale Semiconductor Technical Data Document order number: MC33480 Rev 2.0, 1/2006 Smart Front Corner Light Switch (Triple 10 m and Dual 35 m) The 33480 is designed for low-voltage automotive and industrial lighting applications. Its five low RDS(ON) MOSFETs (three 10 m, two 35 m) can control the high sides of five separate resistive loads (bulbs). Programming, control, and diagnostics are accomplished using a 16-bit SPI interface. Each output has its own PWM control via SPI. The 33480 has highly sophisticated failure mode handling to provide high availability of the outputs. Its multiphase control and output edge shaping improves electromagnetic compatibility (EMC) behavior. The 33480 is packaged in a power-enhanced 12 x 12 nonleaded Power QFN package with exposed tabs. Features * * * * * * * * * * * Triple 10 m and Dual 35 m High-Side Switches 16-bit SPI Communication Interface with Daisy Chain Capability Current Sense Output with SPI-Programmable Multiplex Switch Digital Diagnosis Feature PWM Module with Multiphase Feature Fully Protected Switches Overcurrent Shutdown detection Power Net and Reverse Polarity Protection Low-Power Mode Fail Mode Functions including Autorestart feature External smart power switch control including current recopy 33480 HIGH-SIDE SWITCH Bottom View PNASUFFIX 98ARL10596D 24-TERMINAL PQFN ORDERING INFORMATION Device PC33480PNA/R2 Temperature Range (TA) -40C to 125C Package 24 PQFN 12 V 5.0 V 12 V 33480 VCC LIMP FLASHER IGN RSTB CLOCK CS SO SI SCLK CSNS GND OUT3 OUT4 OUT5 FETIN FETOUT Smart Switch VBAT CP OUT1 OUT2 Watchdog MCU Figure 1. 33480 Simplified Application DiagraM * This document contains information on a product under development. Freescale reserves the right to change or discontinue this product without notice. (c) Freescale Semiconductor, Inc., 2005. All rights reserved. INTERNAL BLOCK DIAGRAM INTERNAL BLOCK DIAGRAM VCC Vcc failure detection IUP Internal Regulator VBAT OV/UV/POR detections CP Charge Pump CS SO SI SCLK IDWN SPI 3.0 MHz PWM Module Logic Gate Drive drain/gate clamp OUT1 Overcurrent Detection Open Load Detection Overtemperature Detection CLOCK LIMP FLASHER IGN RSTB (fault management) OUT1 IDWN RDWN OUT2 OUT2 Overtemperature Prewarning OUT3 OUT3 OUT4 OUT4 OUT5 Selectable Output Current Recopy (Analog MUX) Vcc OUT5 CSNS FETIN Driver for External MOSFET FETOUT GND Figure 2. 33480 Simplified Internal Block Diagram 33480 2 Analog Integrated Circuit Device Data Freescale Semiconductor TERMINAL CONNECTIONS TERMINAL CONNECTIONS FLASHER FETOUT CLOCK RSTB SCLK LIMP VCC 13 12 11 10 CP GND 16 17 9 8 7 6 5 4 3 IGN 2 SO NC CS SI 24 14 GND 23 FETIN 1 CSNS GND 22 OUT1 Definition OUT5 18 15 VBAT 19 OUT4 20 OUT3 21 OUT2 Figure 3. 33480 Terminal Connections (Transparent Top View Of Package) Table 1. 33480 Terminal Definitions A functional description of each terminal can be found in the Functional Terminal Description section beginning on Page 17. Terminal Number 1 2 3 Terminal Name FETIN IGN RSTB Terminal Function Input Input Input Formal Name External FET Input Ignition Input (Active High) Reset This terminal is the current sense recopy of the external SMART MOSFET. This input wakes the device. It also controls the Outputs 1 and 2 in case of Fail mode activation. This terminal has a passive internal pulldown. This input wakes the device. It is also used to initialize the device configuration and fault registers through SPI. This digital terminal has a passive internal pulldown. This input wakes the device. The Fail mode can be activated by this digital input. This terminal has a passive internal pulldown. The PWM frequency and timing are generated from this digital clock input by the PWM module. This terminal has an active internal pulldown current source. The Fail mode can be activated by this digital input. This terminal has an active internal pulldown current source. No internal connection to this terminal. When this digital signal is high, SPI signals are ignored. Asserting this terminal low starts an SPI transaction. The transaction is signaled as completed when this signal returns high. This terminal has an active internal pullup current source. This digital input terminal is connected to the master microcontroller providing the required bit shift clock for SPI communication. This terminal has an active internal pulldown current source. 4 5 6 7 8 FLASHER CLOCK LIMP NC CS Input Input Input NC Input Flasher Input (Active High) Clock Input Limp Home Input (Active High) No Connect Chip Select (Active Low) 9 SCLK Input SPI Clock Input 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 3 TERMINAL CONNECTIONS Table 1. 33480 Terminal Definitions (continued) A functional description of each terminal can be found in the Functional Terminal Description section beginning on Page 17. Terminal Number 10 11 12 13 14,17,23 15 16 18 22 19 20 21 24 Terminal Name SI VCC Terminal Function Input Power Output Output Ground Power Output Output Formal Name Master-Out SlaveIn Logic Supply Master-In SlaveOut External FET Gate Ground Battery Input Charge Pump Output 1 Output 5 Output 2 Output 3 Output 4 Current Sense Output Definition This data input is sampled on the positive edge of the SCLK. This terminal has an active internal pulldown current source. SPI Logic power supply. SPI data is sent to the MCU by this terminal. This data output changes on the negative edge of SCLK and when CS is high, this terminal is high impedance. This terminal controls an external SMART MOSFET by logic level. This output is also called OUT6. This terminal is the ground for the logic and analog circuitry of the device(1). Power supply terminal. This terminal is the connection for an external tank capacitor (for internal use only). Protected 35 m high-side power output to the load. SO FETOUT GND VBAT CP OUT1 OUT5 OUT2 OUT3 OUT4 CSNS Output Protected 10 m high-side power output to the load. Output This terminal is used to output a current proportional to OUT1:OUT5, FET in current, and it is used externally to generate a ground-referenced voltage for the microcontroller to monitor output current. OUT1:OUT5 and FET in choice is SPI programmable. Notes 1. The pins 14, 17 and 23 must be shorted on the board. 33480 4 Analog Integrated Circuit Device Data Freescale Semiconductor MAXIMUM RATINGS MAXIMUM RATINGS Table 2. Maximum Ratings All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or permanent damage to the device. Ratings ELECTRICAL RATINGS Overvoltage Test Range (all OUT[1:5] ON with nominal DC current) 2.0 Hours @ 25C 1.0 Min @ 25C Load Dump (400 ms) @ 25C Reverse Polarity Voltage Range (all OUT[1:5] ON with nominal DC current) 2.0 Min @ 25C VCC Supply Voltage OUT[1:5] Voltage Positive Negative (ground disconnected) Digital Input Current in Clamping Mode (SI, SCLK, CS, IGN, FLASHER, LIMP) SO and FETOUT Outputs Voltage FET in Input Current Outputs clamp energy using single pulse method (L=2mH; R=0; Vbat=14V @150C initial) OUT[1,5] OUT[2:4] ESD Voltage (2) Human Body Model (HBM) Human Body Model (HBM) OUT [1:5] Charge Device Model (CDM) THERMAL RATINGS Operating Temperature Ambient Junction Peak Terminal Re-flow Temperature During Solder Mounting Storage Temperature THERMAL RESISTANCE Thermal Resistance, Junction to Case (4) RJC 1.0 (3) Symbol Value Unit VBAT 20 27 40 VBAT - 15 VCC VOUT 40 -16 IIN VSO IFET in 5.0 - 0.3 to VCC + 0.3 10 -0.3 to 5.5 V V V V mA V mA mJ E1,5 E2,3,4 VESD 2kV 8kV TBD 85 300 V C TA TJ TSOLDER TSTG - 40 to 125 - 40 to 150 260 - 55 to 150 C C K/W Notes 2. ESD testing is performed in accordance with the Human Body Model (HBM) (CZAP = 100 pF, RZAP = 1500 ) and the Charge Device Model. 3. Terminal soldering temperature limit is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may cause malfunction or permanent damage to the device. If the qualification fails, TSOLDER will be changed for 240C. 4. Typical value guaranteed per design. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 5 STATIC ELECTRICAL CHARACTERISTICS STATIC ELECTRICAL CHARACTERISTICS Table 3. Static Electrical Characteristics Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic POWER INPUTS (VBAT, VCC) Battery Supply Voltage Range Full Performance & Short Circuit Extended Voltage Range (5) Battery Supply Undervoltage (UV flag is set ON) Battery Voltage Clamp (OV flaf is set ON) Battery Supply Power on Reset (If Vbat < 5.5V, Vbat = Vcc) VBAT Supply Current @ 25C and VBAT = 12 V and VCC = 5 V Sleep State Current Normal Mode, IGN=5V, RSTB=5V, Outputs Open Digital Supply Voltage Range, Full Performance Digital Supply Undervoltage (VCC Failure) Standby Current Consumption on VCC @ 25C and VBAT = 12 V Output OFF Supply Current Consumption on VCC and VBAT = 12 V No SPI 3.0 MHz SPI Communication LOGIC INPUT/OUTPUT (IGN, CS, CSNS, SI, SCLK, CLOCK, SO, FLASHER, RSTB, LIMP) Input High Logic Level (6) Input Low Logic Level (6) Ignition Threshold Level (IGN) Input Clamp Voltage (IGN) IIGN < 2.5 mA Input Forward Voltage (IGN) IIGN = -2.5 mA Input Active Pulldown Current for LIMP, SI, SCLK and CLOCK inputs Input Active Pullup Current (CS) Input Passive Pulldown Resistance (7) SO High-State Output Voltage IOH = 1.0 mA SO Low-State Output Voltage IOL = -1.6 mA Notes 5. In extended mode, the functionality is guaranteed but not the electrical parameters. 6. Valid for RSTB, SI, SCLK, CLOCK, FLASHER and LIMP terminals. 7. Valid for FLASHER, IGN and RSTB terminals. VSOL - 0.2 0.4 IDWN IUP RDWN VSOH 0.8 TBD - Vcc V VIGNfr - 2.0 5.0 5.0 100 - - - 200 -0.3 20.0 20.0 400 A A k VIH VIL VIGNth VIGNcl 7.0 - 14.0 V 0.7 - 2.0 - - - - 0.3 4.0 Vcc Vcc V V IBATSLEEP IBAT VCC VCCUV - - 4.5 2.5 - 0.5 10.0 - 3.0 TBD - - 5.0 20.0 5.5 3.5 5.0 mA - - 1.0 5.0 A mA V V A VBATUV VBATCLAMP VBATPOR VBAT 7.0 6.0 5.0 41.0 - - - 5.3 47.0 4.2 18.0 20.0 6.0 53.0 5.0 V V V V Symbol Min Typ Max Unit IQCC ICC 33480 6 Analog Integrated Circuit Device Data Freescale Semiconductor STATIC ELECTRICAL CHARACTERISTICS Table 3. Static Electrical Characteristics (continued) Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic LOGIC INPUT/OUTPUT (IGN, CS, CSNS) (CONTINUED) SO Tri-State Leakage Current CS > 0.7 VCC Symbol Min Typ Max Unit ISOLEAK - 1.0 VCSNS 5.0 0.0 6.0 1.0 7.0 A V Current Sense Output Clamp Voltage ICSNS<10mA OUTPUTS (OUT 1-5) Output Negative Clamp Voltage IOUT = - 500 mA, Outputs OFF Drain to Source Clamp Voltage IOUT = + 500 mA, Outputs shorted to ground IOUT =OCHI, this parameter is guaranteed by design Current Sense Output Precision (8) Full-Scale Range (FSR) 0.75 FSR 0.50 FSR 0.25 FSR 0.10 FSR Temperature Drift of Current Sense Output (9) VBAT=13.5V, IOUT1,5=2.8 A, IOUT2-4=5.5 A, reference taken at TA=25C Over Temperature Shutdown Thermal PreWarning PARKING LIGHT OUT1 Output Drain-to-Source ON Resistance (IOUT = 2.8 A, TA = 25C) VBAT = 13.5 V VBAT = 7.0 V Output Drain-to-Source ON Resistance (IOUT = 2.8 A, VBAT = 13.5 V, TA = 150C) (10) Reverse Output ON Resistance (IOUT = -2.8 A, TA = 25C) (11) VBAT = -12 V High Over Current Shutdown Threshold 1(10) VBAT = 16 V, TA = -40C VBAT = 16 V, TA = 25C VBAT = 16 V, TA = 125C VOUT - 20.0 VDSCLAMP 41.0 47.0 53.0 - -16.0 V V ICS / ICS - - - - ICS /T - TBD TBD TBD TBD TBD TBD TBD TBD TBD 400 % ppm/C TOTS TOTSWARN 160 110 175 125 190 140 C C RDS(ON) - - RDS(ON) - RSD(ON) - IOCHI1 27.7 TBD TBD TBD - 34.6 TBD 34.6 TBD 70 38.9 TBD TBD TBD - 59.5 - - 35 55 m m m A Notes 8. TA = 25C. ICS / ICS= (measured ICS - targeted ICS)/ targeted ICS with targeted ICS=5mA 9. Based on statistical data. Not production tested. ICS /T= [(measured ICS at T1 - measured ICS at T2) / measured ICS at room] / (T1 - T2) 10. 11. Parameter guaranteed by design; however, it is not production tested. Source-to-Drain ON Resistance (Reverse Drain-to-Source ON Resistance) with negative polarity VBAT. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 7 STATIC ELECTRICAL CHARACTERISTICS Table 3. Static Electrical Characteristics (continued) Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic PARKING LIGHT OUT1(CONTINUED) High Over Current Shutdown Threshold 2 Low Over Current Shutdown Threshold Open Load Current Threshold in ON State (12) Open Load Current Threshold in ON State with LED (13) VOUT = VBAT - 0.5 V Current Sense Full-Scale Range (14) Symbol Min Typ Max Unit IOCHI2 IOCLO IOL IOLLED 11.9 5.6 0.05 5.0 14.9 6.7 0.2 10.0 6.0 - - 17.9 7.7 0.5 20.0 - - - A A A mA ICS FSR RSC1(OUT1) RSC2(OUT1) - TBD TBD A m m Severe short-circuit impedance detection for Vbat=20V without artificial network (15) Severe short-circuit impedance detection for Vbat=20V with artificial network L=10H, R=20mohm (15) LOW BEAM OUT2 Output Drain-to-Source ON Resistance (IOUT = 5.5 A, TA = 25C) VBAT = 13.5 V VBAT = 7.0 V Output Drain-to-Source ON Resistance (IOUT = 2.8 A, VBAT = 13.5 V, TA = 150C) (15) Reverse Source-to-Drain ON Resistance (IOUT = -2.8 A, TA = 25C) (16) VBAT = -12 V High Over Current Shutdown Threshold 1(15) VBAT = 16 V, TA = -40C VBAT = 16 V, TA = 25C VBAT = 16 V, TA = 125C High Over Current Shutdown Threshold 2 Low Over Current Shutdown Threshold Optional Xenon Bulb Optional H7 Bulb Open Load Current Threshold in ON State (17) Open Load Current Threshold in ON State with LED (18) VOL = VBAT - 0.5 V Current Sense Full-Scale Range(19) Optional Xenon Bulb Optional H7 Bulb Notes 12. 13. 14. 15. 16. 17. 18. 19. RDS(ON) - - RDS(ON) - RSD(ON) - IOCHI1 61.6 TBD TBD TBD IOCHI2 IOCLO 18.6 12.4 IOL IOLLED 5.0 ICS FSR - - 20.0 13.3 - - 10.0 20.0 0.1 22.2 14.8 0.4 25.8 17.2 1.0 26.5 - 77.0 TBD 77.0 TBD 33.2 20 92.4 TBD TBD TBD 39.8 - 17.0 - - 10 15 m m m A A A A mA A OLLED1, bit D0 in SI data is set to [0]. OLLED1, bit D0 in SI data is set to [1]. For typical value of ICS FSR, ICSNS = 5.0 mA. If the range is exceeded, no current clamp and the precision is no more guaranteed. Parameter guaranteed by design; however, it is not production tested. Source-to-Drain ON Resistance (Reverse Drain-to-Source ON Resistance) with negative polarity VBAT.. OLLED2, bit D1 in SI data is set to [0]. OLLED2, bit D1 in SI data is set to [1]. For typical value of ICS FSR, ICSNS = 5.0 mA. If the range is exceeded, no current clamp and the precision is no more guaranteed 33480 8 Analog Integrated Circuit Device Data Freescale Semiconductor STATIC ELECTRICAL CHARACTERISTICS This paragraph is boilerplate - you may add to it but, can not change wording. You may change numeric values Table 3. Static Electrical Characteristics (continued) Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic LOW BEAM OUT2 (continued) Severe short-circuit impedance detection for Vbat=20V without artificial network (20) Severe short-circuit impedance detection for Vbat=20V with artificial network L=10H, R=20mohm (20) HIGH BEAM OUT3 Output Drain-to-Source ON Resistance (IOUT = 5.5 A, TA = 25C) VBAT = 13.5 V VBAT = 7.0 V Output Drain-to-Source ON Resistance (IOUT = 2.8 A, VBAT = 13.5 V, TA = 150C) (20) Symbol Min Typ Max Unit RSC1(OUT2) RSC2(OUT2) TBD TBD - - - - m m RDS(ON)25 - - RDS(ON)150 - RSD(ON)25 - IOCHI1 IOCHI1_40 IOCHI1_25 IOCHI1_125 IOCHI2 IOCLO 61.6 TBD TBD TBD 26.5 12.4 0.1 - 77.0 TBD 77.0 TBD 33.2 14.8 0.4 20 92.4 TBD TBD TBD 39.8 17.2 1.0 - 17.0 - - 10 15 m m Reverse Source-to-Drain ON Resistance (IOUT = -2.8 A, TA = 25C) (21) VBAT = -12 V High Over Current Shutdown Threshold 1 VBAT = 16 V, TA = -40C VBAT = 16 V, TA = 25C VBAT = 16 V, TA = 125C High Over Current Shutdown Threshold 2 Low Over Current Shutdown Threshold Open Load Current Threshold in ON State (22) (23) m A A A A mA IOL IOLLED Open Load Current Threshold in ON State with LED VOL = VBAT - 0.5 V Current Sense Full-Scale Range (24) 5.0 ICS FSR RSC1(OUT3) RSC2(OUT3) - TBD TBD 10.0 13.3 - - 20.0 - - - A m m Severe short-circuit impedance detection for Vbat=20V without artificial network (20) Severe short-circuit impedance detection for Vbat=20V with artificial network L=10H, R=20mohm (20) Notes 20. Parameter guaranteed by design; however, it is not production tested. 21. Source-to-Drain ON Resistance (Reverse Drain-to-Source ON Resistance) with negative polarity VBAT. 22. 23. 24. OLLED3, bit D2 in SI data is set to [0]. OLLED3, bit D2 in SI data is set to [1]. For typical value of ICS FSR, ICSNS = 5.0 mA. If the range is exceeded, no current clamp and the precision is no more guaranteed. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 9 STATIC ELECTRICAL CHARACTERISTICS Table 3. Static Electrical Characteristics (continued) Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic FOG LIGHT OUT4 Output Drain-to-Source ON Resistance (IOUT = 5.5 A, TA = 25C) VBAT = 13.5 V VBAT = 7.0 V Output Drain-to-Source ON Resistance (IOUT = 2.8 A, VBAT = 13.5 V, TA = 150C) (25) Symbol Min Typ Max Unit RDS(ON)25 - - RDS(ON)150 - RSD(ON)25 - IOCHI1 IOCHI1_40 IOCHI1_25 IOCHI1_125 IOCHI2 IOCLO IOL IOLLED 5.0 ICS FSR RSC1(OUT4) RSC2(OUT4) - TBD TBD 10.0 13.3 - - 20.0 - - - 61.6 TBD TBD TBD 26.5 12.4 0.1 - 77.0 TBD 77.0 TBD 33.2 14.8 0.4 20 92.4 TBD TBD TBD 39.8 17.2 1.0 - 17.0 - - 10 15 m m Reverse Source-to-Drain ON Resistance (IOUT = -2.8 A, TA = 25C) (26) VBAT = -12 V High Over Current Shutdown Threshold 1 (25) VBAT = 16 V, TA = -40C VBAT = 16 V, TA = 25C VBAT = 16 V, TA = 125C High Over Current Shutdown Threshold 2 Low Over Current Shutdown Threshold Open Load Current Threshold in ON State (27) Open Load Current Threshold in ON State with LED (28) VOL = VBAT - 0.5 V Current Sense Full-Scale Range (29) Severe short-circuit impedance detection for Vbat=20V without artificial network (25) Severe short-circuit impedance detection for Vbat=20V with artificial network L=10H, R=20mohm (25) FLASHER OUT5 Output Drain-to-Source ON Resistance (IOUT = 2.8 A, TA = 25C) VBAT = 13.5 V VBAT = 7.0 V m A A A A mA A m m RDS(ON)25 - - - - 35 55 m Notes 25. Parameter guaranteed by design; however, it is not production tested. 26. Source-to-Drain ON Resistance (Reverse Drain-to-Source ON Resistance) with negative polarity VBAT. 27. 28. 29. OLLED4, bit D3 in SI data is set to [0]. OLLED4, bit D3 in SI data is set to [1]. For typical value of ICS FSR, ICSNS = 5.0 mA. If the range is exceeded, no current clamp and the precision is no more guaranteed. 33480 10 Analog Integrated Circuit Device Data Freescale Semiconductor Table 3. Static Electrical Characteristics (continued) Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic FLASHER OUT5 (CONTINUED) Output Drain-to-Source ON Resistance (IOUT = 2.8 A, VBAT = 13.5 V, TA = 150C) (30) Symbol Min Typ Max Unit RDS(ON)150 - RSD(ON)25 - IOCHI1 IOCHI1_40 IOCHI1_25 IOCHI1_125 IOCHI2 IOCLO 27.7 TBD TBD TBD 11.9 5.6 0.05 - 34.6 TBD 34.6 TBD 14.9 6.7 0.2 70 38.9 TBD TBD TBD 17.9 7.7 0.5 - 59.5 m Reverse Source-to-Drain ON Resistance (IOUT = -2.8 A, TJ = 25C) (31) VBAT = -12 V High Over Current Shutdown Threshold 1 (30) VBAT = 16 V, TA = -40C VBAT = 16 V, TA = 25C VBAT = 16 V, TA = 125C High Over Current Shutdown Threshold 2 Low Over Current Shutdown Threshold Open Load Current Threshold in ON State (32) m A A A A mA IOL IOLLED Open Load Current Threshold in ON State with LED (33) VOL = VBAT - 0.5 V Current Sense Full-Scale Range (33) Severe short-circuit impedance detection for Vbat=20V without artificial network (30) Severe short-circuit impedance detection for Vbat=20V with artificial network L=10H, R=20mohm (30) SPARE FETOUT / FETIN FET out Output High Level @ I = 1.0 mA FET out Output Low Level @ I = -1.0 mA FET in Input Full Scale Range Current FET in Input Clamp Voltage IFET in= 5mA, CSNS open Drop Voltage on FET in (FET in - CSNS) IFET in= 5mA, CSNS = 5V 5.0 ICS FSR RSC1(OUT5) RSC2(OUT5) - TBD TBD 10.0 6.0 - - 20.0 - - - A m m VH MAX VH MIN IFET in VCLIN 0.8 - - 5.3 - 0.2 5.0 - - - 0.4 - 7.0 VCC V mA V V VDRIN 0.0 0.3 Notes 30. Parameter guaranteed by design; however, it is not production tested. 31. Source-to-Drain ON Resistance (Reverse Drain-to-Source ON Resistance) with negative polarity VBAT. 32. 33. 34. OLLED5, bit D4 in SI data is set to [0]. OLLED5, bit D4 in SI data is set to [1]. For typical value of ICS FSR, ICSNS = 5.0 mA. If the range is exceeded, no current clamp and the precision is no more guaranteed. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 11 DYNAMIC ELECTRICAL CHARACTERISTICS DYNAMIC ELECTRICAL CHARACTERISTICS Table 4. Dynamic Electrical Characteristics Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic POWER OUTPUTS TIMING (OUT1 to OUT5) Current Sense rising and falling Settling Time on resistive load only (Maximum Value, 5%) Current Sense rising and falling Settling Time on resistive load only (Maximum Value, 1%) Driver Output Positive Slew Rate (30% to 70% @ VBAT = 14 V) IOUT = 2.8 A for OUT1 and OUT5 IOUT = 5.5 A for OUT2, OUT3, and OUT4 Driver Output Negative Slew Rate (70% to 30% @ VBAT = 14 V) IOUT = 2.8 A for OUT1 and OUT5 IOUT = 5.5 A for OUT2, OUT3, and OUT4 Driver Output Matching Slew Rate (SRR /SRF) (70% to 30% @ VBAT = 14 V @25C) IOUT = 2.8 A for OUT1 and OUT5 IOUT = 5.5 A for OUT2, OUT3, and OUT4 Driver Output Turn-ON Delay (SPI ON Command [No PWM, CS Positive Edge] to Output = 50% VBAT @ VBAT = 14 V) ( IOUT = 2.8 A for OUT1 and OUT5 IOUT = 5.5 A for OUT2, OUT3, and OUT4 Driver Output Turn-OFF Delay (SPI OFF command [CS Positive Edge] to Output = 50% VBAT @ VBAT = 14 V) (see Figure4, p14) IOUT = 2.8 A for OUT1 and OUT5 IOUT = 5.5 A for OUT2, OUT3, and OUT4 Driver Output Matching Time (t DLY(ON) - t DLY(OFF)) @ Output = 50% VBAT with VBAT = 14 V, f PWM = 240 Hz, PWM = 50%, @25C IOUT = 2.8 A for OUT1 and OUT5 IOUT = 5.5 A for OUT2, OUT3, and OUT4 t RF - 25 - 25 0 0 25 25 SR 0.8 0.8 1.0 1.0 1.2 1.2 s 40 40 80 80 160 (TBC) 160 (TBC) s 40 40 80 80 160 (TBC) 160 (TBC) s SRF 0.2 0.2 0.4 0.4 0.8 0.8 Symbol Min Typ Max Unit t R5 / t F5 t R1 / t R5 SRR - - 2 TBD 10 TBD s s V/s 0.2 0.2 0.4 0.4 0.8 0.8 V/s t DLYON t DLYOFF PWM MODULE PWM Frequency Range Clock Input Frequency Range Output PWM Duty Cycle maximum range for 11V 60.0 7.68 4.0 6.2 (TBC) - - - - 240.0 30.72 96.0 96.0 (TBC) Hz kHz % % WATCHDOG TIMING Watchdog Timeout (SPI Failure) t WDTO 50 75 100 ms I/O PLAUSIBILITY CHECK TIMING Fault Shutdown Delay Time (from Overtemperature or OCHI1 or OCHI2 or OCLO Fault Detection to Output = 50% VBAT without round shaping feature t SD - 7 30 s for turn off) 33480 12 Analog Integrated Circuit Device Data Freescale Semiconductor DYNAMIC ELECTRICAL CHARACTERISTICS Table 4. Dynamic Electrical Characteristics Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic Symbol Min Typ Max Unit I/O PLAUSIBILITY CHECK TIMING (CONTINUED) High Overcurrent Threshold Time 1 for OUT1 and OUT5 for OUT2:4 High Overcurrent Threshold Time 2 for OUT1 and OUT5 for OUT2:4 Autorestart Period for OUT1 and OUT5 for OUT2 Autorestart Overcurrent Shutdown Delay Time for OUT1 and OUT5 for OUT2 Limp Home Input pin Deglicher Time Cyclic Open Load Detection Timing with LED (37) Flasher Toggle Timeout Ignition Toggle Timeout Clock Input Low Frequency Detection Range Clock Input High Frequency Detection Range t OCHIARS t OCHIARS t LIMP 3.5 7.0 7.0 105 1.4 1.4 1.0 100 5.0 10.0 10.0 150 TBD TBD 2.0 200 6.5 13.0 13.0 195 TBD TBD 4.0 400 ms ms s s kHz kHz ms t OUT1 t OUT2 t OUT1 t OUT2 tAUTORST-T1 tAUTORST-T2 7 14 10 20 13 26 ms 52.5 105 75 150 97.5 195 ms 52.5 105 75 150 97.5 195 ms t OLLED t FLASHER t IGNITION f LCLK det f HCLK det Notes 35. The PWM ratio is measured at Vout = 50% of VBAT in nominal range of PWM frequency (from 60Hz to 200Hz). It is possible to put the device fully on (PWM duty cycle = 100%) and fully off (PWM duty cycle = 0%). Between 4%-96%, OCHI1,2, OCLO and open load are available in ON state.See Figure 4, Input Timing Switching Characteristics 36. Linear range is defined by output duty cycle to SPI duty cycle configuration +/-1 LSB. For values outside linear duty cycle range, a calibration curve is available. 37. IOLLEDn bit (where "n" corresponds to respective outputs 1 through 5) in SI data is set to logic [1]. Refer to Table 8, Serial Input Address and Configuration Bit Map, page 28. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 13 DYNAMIC ELECTRICAL CHARACTERISTICS Table 4. Dynamic Electrical Characteristics Characteristics noted under conditions 4.5 V VCC 5.5 V, 7.0 V VBAT 18 V, - 40C TA 125C, GND = 0 V unless otherwise noted. Typical values noted reflect the approximate parameter means at TA = 25C under nominal conditions unless otherwise noted. Characteristic SPI INTERFACE CHARACTERISTICS Maximum Frequency of SPI Operation Rising Edge of CS to Falling Edge of CS (Required Setup Time) (38) (38) Symbol Min Typ Max Unit f SPI t CS t LEAD t WSCLKh t WSCLKl (38) - - - - - - - - - - 50 - - 50 25 25 3.0 300 167 167 167 167 83 83 MHz ns ns ns ns ns ns ns ns Falling Edge of CS to Rising Edge of SCLK (Required Setup Time) Required High State Duration of SCLK (Required Setup Time) Required Low State Duration of SCLK (Required Setup Time) (38) (38) Falling Edge of SCLK to Rising Edge of CS (Required Setup Time) SI to Falling Edge of SCLK (Required Setup Time) Falling Edge of SCLK to SI (Required Setup Time) SO Rise Time CL = 200 pF SO Fall Time CL = 200 pF SI, CS, SCLK, Incoming Signal Rise Time SI, CS, SCLK, Incoming Signal Fall Time (39) (39) (39) t LAG t SI(SU t SI HOLD t RSO - 25 50 ns t FSO - 25 - - - 65 50 50 50 145 145 t RSI t FSI (40) (41) - - - - ns ns ns ns ns (39) Time from Falling Edge of CS to SO Low Impedance Time from Rising Edge of CS to SO High Impedance Time from Rising Edge of SCLK to SO Data Valid 0.2 Vcc SO 0.7 Vcc, CL = 200 pF Notes 38. 39. 40. 41. 42. t SO(EN) t SO(DIS) t VALID (42) - 65 105 Maximum setup time required for the 33480 is the minimum guaranteed time needed from the microcontroller. Rise and Fall time of incoming SI, CS, and SCLK signals suggested for design consideration to prevent the occurrence of double pulsing. Time required for output status data to be available for use at SO. 1.0 k on pullup on CS. Time required for output status data to be terminated at SO. 1.0 k on pullup on CS. Time required to obtain valid data out from SO following the rise of SCLK. 33480 14 Analog Integrated Circuit Device Data Freescale Semiconductor TIMING DIAGRAMS TIMING DIAGRAMS VIH V IH RSTB RST 0.2 VDD 0.2 VDD TwRSTB t ENBL VIL VIL t CS TCSB TENBL 0.7 Vcc 0.7VDD CS CSB 0.2 Vcc 0.7VDD tTlead LEAD t WSCLKh TwSCLKh t RSI TrSI VIH V IH VIL V IL SCLK SCLK 0.7 Vcc 0.7VDD 0.2 Vcc 0.2VDD t LAG Tlag VIH VIH VIL V t TSIsu SI(SU) t WSCLKl TwSCLKl t SI(HOLD) TSI(hold) IL tTfSI FSI VIH V Valid Don't Care IH SI SI Don't Care 0.7 VDD 0.7 Vcc 0.2VDD 0.2 Vcc Valid Don't Care VIL VIL Figure 4. Input Timing Switching Characteristics t RSI t FSI TrSI 3.5 3.5V V TfSI VOH VOH 50% 1.0V 1.0 V VOL VOL SCLK SCLK t SO(EN) TdlyLH SO SO 0.7 Vcc VDD VOH VOH VOL VOL 0.2 VDD 0.2 Vcc TrSO t RSO TVALID tVALID Low-to-High Low to High SO SO 0.7 Vcc High to Low High-to-Low 0.7 VDD TfSO t FSO VOH VOH TdlyHL tSO(DIS) 0.2VDD 0.2 Vcc VOL VOL Figure 5. SCLK Waveform and Valid SO Data Delay Time 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 15 FUNCTIONAL DESCRIPTION INTRODUCTION FUNCTIONAL DESCRIPTION INTRODUCTION The 33480 is designed for low-voltage automotive and industrial lighting applications. Its five low RDS(ON) MOSFETs (three 10 m and two 35 m) can control the high sides of five separate resistive loads (bulbs). Programming, control, and diagnostics are accomplished using a 16-bit SPI interface. FUNCTIONAL TERMINAL DESCRIPTION SUPPLY VOLTAGE (VBAT) The VBAT terminal of the 33480 is the power supply of the device. In addition to its supply function, this tab contributes to the thermal behavior of the device by conducting the heat from the switching MOSFETs to the printed circuit board. SUPPLY VOLTAGE (VCC) This is an external voltage input terminal used to supply the SPI digital portion of the circuit and the gate driver of the external SMART MOSFET. GROUND (GND) This terminal is the ground of the device. CLOCK INPUT (CLOCK) The PWM frequency and timing are generated from clock input by the PWM module. The clock input frequency is the factor 27 = 128 of the PWM frequency (60 Hz to 240 Hz). The OUT1:6 can be controlled in the range of 4% to 96% with a resolution of 7 bits of duty cycle (bits D[6:0]). The following table describes the PWM resolution. On/Off (Bit D7) 0 1 1 1 1 Duty cycle (7 bits resolution) X 0000000 0000001 0000010 1111111 Output state OFF PWM (1/128 duty cycle) PWM (2/128 duty cycle) PWM (3/128 duty cycle) fully ON The synchronization of the switching phases between different corner light IC is provided by an SPI command in combination with the CS input. The bit in the SPI is called PWM sync (initialization register). In Normal Mode, no PWM feature (100% duty cycle) is provided in the following instances: * with the following SPI configuration: D7:D0=FF. * In case of clock input signal failure (out of f PWM), the outputs state depends of D7 bit value (D7=1=ON) in Normal Mode. In Fail mode. The ouputs state depends of IGN and Flasher terminals. The timing includes four programmable PWM switching phases (0, 90, 180, and 270) to improve overall EMC behavior of the light module. The amplitude of the input current is divided by four while the frequency is 4 times the original one. The two following pictures illustrate this behavior. LIMP HOME INPUT (LIMP) The Fail mode of the component can be activated by this digital input port. The signal is "high active", meaning the Fail mode can be activated by a logic high signal at the input. 33480 16 Analog Integrated Circuit Device Data Freescale Semiconductor FUNCTIONAL DESCRIPTION FUNCTIONAL TERMINAL DESCRIPTION IGNITION INPUT (IGN) The ignition input wakes the device. It also controls the Fail mode activation. The signal is "high active", meaning the component is active in case of a logic high at the input. FETout is not protected in case of short circuit or undervoltage on Vbat. In case of reverse battery, OUT6 is OFF. FET IN INPUT (FETIN) FLASHER INPUT (FLASHER) The flasher input wakes the device. It also controls the Fail Mode activation. The signal is "high active", meaning the component is active in case of a logic high at the input. This input terminal gives the current recopy of the external MOSFET. It can be routed on CSNS output by SPI command. SPI PROTOCOL DESCRIPTION The SPI interface has a full-duplex, three-wire synchronous data transfer with four I/O lines associated with it: Serial Clock (SCLK), Serial Input (SI), Serial Output (SO), and Chip Select (CS). The SI/SO terminals of the 33480 device follow a first-in, first-out (D15 to D0) protocol, with both input and output words transferring the most significant bit (MSB) first. All inputs are compatible with 5.0 V CMOS logic levels, supplied by Vcc. The SPI lines perform the following functions: RESET INPUT (RSTB) This input wakes the device when the RSTB terminal is at logic [1]. It is also used to initialize the device configuration and the SPI faults registers when the signal is low. All SI/SO registers described Table 8 and Table 11 are reset. The fault management is not affected by RSTB (see Figure 2). CURRENT SENSE OUTPUT (CSNS) The current sense output terminal is an analog current output. The routing to the external resistor is SPI programmable. SERIAL CLOCK (SCLK) The SCLK terminal clocks the internal shift registers of the 33480 device. The SI terminal accepts data into the input shift register on the falling edge of the SCLK signal, while the SO terminal shifts data information out of the SO line driver on the rising edge of the SCLK signal. It is important that the SCLK terminal be in a logic low state whenever CS makes any transition. For this reason, it is recommended the SCLK terminal be in a logic [0] whenever the device is not accessed (CS logic [1] state). SCLK has an internal pulldown, IDWN. When CS is logic [1], signals at the SCLK and SI terminals are ignored and SO is tri-stated (high impedance) (see Figure 6). CHARGE PUMP (CP) An external capacitor is connected between this terminal and VBAT terminal. It is used as a tank for the internal charge pump. Its value is 100 nF 20%, 25V maximum. FET OUT OUTPUT (FETOUT) This output terminal is used to control an external MOSFET (OUT6). The high level of the FETout Output is Vcc if Vbat and Vcc are available in case of FETout is controlled ON. CSB CS CS SCLK SI D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 SO OD15 OD14 OD13 OD12 OD11 OD10 OD9 OD8 OD7 OD6 OD5 OD4 OD3 OD2 OD1 OD0 NOTES: 1. 2. 3. RSTB is in a logic1. state duringrelate to the most recent ordered entry of data into the device. H D15 : D0 the above operation. device. DO, D1, D2, ... , and OD15 : OD0 relate recent ordered entry of of ordered fault and status data out of the device. 2. D15 relate to the most to the first 16 bits program data into the LUX IC device. OD0, OD1, OD2, ..., and OD15 relate to the first 16 bits of ordered fault and status data out of the LUX IC Notes Figure 6. Single 16-Bit Word SPI Communication 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 17 FUNCTIONAL DESCRIPTION FUNCTIONAL TERMINAL DESCRIPTION SERIAL INPUT (SI) The SI terminal is a serial interface command data input terminal. Each SI bit is read on the falling edge of SCLK. A 16-bit stream of serial data is required on the SI terminal, starting with D15 to D0. SI has an internal pulldown, Idown. CHIP SELECT (CS) The CS terminal enables communication with the master device. When this terminal is in a logic [0] state, the device is capable of transferring information to, and receiving information from, the master device. The 33480 device latches in data from the Input Shift registers to the addressed registers on the rising edge of CS. The device transfers status information from the power output to the Shift register on the falling edge of CS. The SO output driver is enabled when CS is logic [0]. CS should transition from a logic [1] to a logic [0] state only when SCLK is a logic [0]. CS has an internal pullup, IUP. SERIAL OUTPUT (SO) The SO data terminal is a tri-stateable output from the shift register. The SO terminal remains in a high-impedance state until the CS terminal is put into a logic [0] state. The SO data is capable of reporting the status of the output, the device configuration, and the state of the key inputs. The SO terminal changes state on the rising edge of SCLK and reads out on the falling edge of SCLK. 33480 18 Analog Integrated Circuit Device Data Freescale Semiconductor FUNCTIONAL DEVICE OPERATION OPERATIONAL MODES FUNCTIONAL DEVICE OPERATION OPERATIONAL MODES SLEEP MODE The Sleep mode is the default mode of the 33480. This is the state of the device after first applying battery voltage (VBAT) and prior to any I/O transitions. This is also the state of the device when IGN, FLASHER, and RSTB are logic [0] (wake=0). In the Sleep mode, the outputs and all internal circuitry are OFF to minimize current draw. In addition, all SPI-configurable features of the device are reset. The 33480 will transit to two modes (Normal and Fail) depending on wake and fail signals (see Fig13). The transition to the other modes is according following signals : * Wake = IGN or IGN_ON or FLASHER or FLASHER_ON or RSTB * Fail = VCC fail or SPI fail or External limp D7 bit D0-D6 bits Output Overcurrent FAIL MODE The 33480 is in Fail mode when: * Wake = 1 * Fail = 1. NORMAL MODE The 33480 is in Normal mode when: * Wake = 1 * Fail = 0 In Normal operating mode the power outputs are under full control of the SPI as follows: * The outputs 1 to 6, including multiphase timing, are controlled by the programmable PWM module. * The outputs 1 to 5 are switched OFF in case of undervoltage on Vbat. * The outputs 1 to 5 are protected by the overcurrent double window and overtemperature shutdown circuit. * The digital diagnosis feature transfers status of the smart outputs via SPI. * The analog current sense output (current recopy feature) can be routed by SPI. * The SPI reports NM=1 in this mode. The figure below describes the PWM, outputs and overcurrent behavior in Normal Mode. In Fail mode : * The outputs are under control of external terminals (see Table 5) * The outputs are fully protected in case of overload, overtemperature and undervoltage (on Vbat or on Vcc). * Neither digital diagnosis feature (SPI) nor analog current sense are available. * Output 2 is configured in Xenon mode. * In case of overload (OCHI2 or OCLO) conditions or undervoltage on Vbat, the outputs are under control of autorestart feature. * In case of serious overload condition (OCHI1 or OT) the corresponding output is latched OFF until a new wake up event (wake=0 then 1). IGN_ON IGN (external) OUT[1,2] Overcurrent 1.4 sec min Table 5. Limp Home Output State Output 1 Parking Light IGN Terminal Output 2 Low Beam IGN Terminal Output 3 High Beam OFF Output 4 Fog Light OFF Output 5 Flasher FLASHER Terminal External Switch Spare OFF 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 19 FUNCTIONAL DEVICE OPERATION OPERATIONAL MODES AUTORESTART STRATEGY The autorestart circuitry is used to supervise the outputs and reactivate high-side switches in case of overload or undervoltage failure conditions to provide a high availability of the outputs. Autorestart feature is available in Fail mode when no supervising intelligence of the microcontroller is available. Autorestart is activated in case of overload condition (OCHI2 or OCLO) or undervoltage condition on VBat (see Fig10). The autorestart switches ON the outputs. During ON state of the switch OCHI1 window is enable for tochi_Auto then after the output is protected by OCLO. In case of OCHI1 or OT, the switch is latched OFF until wake up (wake=0 then1). In case of OCLO or undervoltage, the output switch OFF and after autorestart period (150ms for 10mohm or 75ms for 35mhom) turn ON again. In case of under voltage occurred in fail mode, it will be latched twice: one latch for outputs 1 and 5 and the second latch for output 2. That means the corresponding output is switched on only after its autorestart period (tAUTORST-T1 or tAUTORST-T2). The Autorestart is not limited in time. TRANSITION FAIL TO NORMAL MODE To leave the fail mode, the fail condition must be removed (fail=0). The microcontroller has to send a SPI command with D10 must be to logic [1] to reset the watchdog bit ; the other bits are not considered. The previous latched faults are reset by the transition into Normal mode. Output current OCHI1 TRANSITION NORMAL TO FAIL MODE OCLO or UV fault To leave the Normal Mode, a fail condition must occur (fail=1). The previous latched faults are reset by the transition into Fail mode. OCLO tochi_auto Auto period time Figure 7. Overcurrent window in case of Autorestart 33480 20 Analog Integrated Circuit Device Data Freescale Semiconductor OPERATIONAL MODES (wake=0) Sleep (fail=0) and (wake=1) (wake=0) (wake=1) and (fail=1) * VBAT > VBATPOR VBAT < VBATPOR VBAT < VBATPOR Power OFF VBAT < VBATPOR Normal Fail (fail=0) and (wake=1) (fail=1) and (wake=1) Notes: * only available in case of Vcc fail condition wake=(RSTB=1) OR (IGN_ON=1) OR (Flasher_ON=1) fail=(Vcc_fail=1) OR (SPI_fail=1) OR (ext_limp=1) Figure 8. Operating Modes State Machine START-UP SEQUENCE The 33480 enters in Normal Mode after start-up if following sequence is provided: * Vbat and Vcc power supplies must be above their undervoltage thresholds (Sleep mode). * generate wake up event (wake=1) from 0 to 1 on RSTB. The device switches to normal mode. * apply PWM clock after maximum 200us (min 50us). * send SPI command to the Device status register to clear the clock fail flag to enable the PWM module to start. If the correct start-up sequence is not provided, the PWM function is not guaranteed. The following figure describes the wake-up block diagram. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 21 OPERATIONAL MODES Vbat wake Vcc Wake-up bar Internal regulator Dig5V Oscillator 500kHz SPI registers IGN Deglitcher (Note*) IGN_ON Fault management PWM freq detector PWM module reset Flasher Deglitcher (Note*) Flasher_ON Vcc fail SPI fail External Limp OR Fail RSTB Figure 9. Wake-up block diagram Note*: 1.4 sec min external external_ON external: IGN, Flasher external_ON: IGN_ON, Flasher_ON 33480 22 Analog Integrated Circuit Device Data Freescale Semiconductor PROTECTION AND DIAGNOSIS FEATURES PROTECTION AND DIAGNOSIS FEATURES Output Protection Features The 33480 provides the following protection features: * Protection against transients on VBAT supply line (per ISO 7637) * Active clamp, including protection against negative transients on output line * Overtemperature * Severe and resistive Overcurrent * Open Load during ON state These protections are provided for each output (OUT1:5). Overtemperature detection The 33480 provides overtemperature shutdown for each output (OUT1:OUT5 ). It can occur when the output terminal is in the ON or OFF state. An overtemperature fault condition results in turning OFF the corresponding output. The fault is latched and reported via SPI. To delatch the fault and be able to turn ON again the outputs, the failure condition must be removed (T< 175C typically) and: * if the device was in Normal Mode, the output corresponding register (bit D7) must be rewritten. Application of complete OCHI window (OCHI1+OCHI2 during t2) depends on toggling or not toggling D7 bit. * if the device was in Fail Mode, the corresponding output is locked until restart of the device: wake up from Sleep Mode or VBATPOR. The SPI fault report (OTS bit) is removed after a read operation. Overcurrent detections The 33480 provides intelligent overcurrent shutdown (see Figure 10) in order to protect the internal power transistors and the harness in the event of overload (fuse characteristic). Output current OCHI (IOCHI1 and then IOCHI2) is only activated after toggling D7 bit in Normal Mode. In Fail Mode, the control of OCHI window is provided by the toggles: IGN_ON, Flasher_ON. The current thresholds (IOCHI1 , IOCHI2 and IOCLO) and the time (t1 and t2) are fixed numbers for each driver. After t2, OCLO current threshold is set to protect in steady state. OUT2 is default loaded with the Xenon profile. The use of H7 bulbs at this output requires SPI programming (Xenon bit). In case of overload (OCHI1 or OCHI2 or OCLO detection), the corresponding output is disabled immediately. The fault is latched and the status is reported via SPI. To delatch the fault, the failure condition must be removed and: For OCHI1: * if the device was in Normal Mode: the output corresponding register (bit D7) must be rewritten D7=1. Application of complete OCHI window depends on toggling or not toggling D7 bit. * if the device was in Fail Mode, the failure is locked until restart of the device: wake up from Sleep Mode or VBATPOR. For OCHI2 and OCLO: * if the device was in Normal Mode: the output corresponding register (bit D7) must be rewritten D7=1. Application of complete OCHI window depends on toggling or not toggling D7 bit. * if the device was in Fail Mode, Autorestart is activated. The device Autorestart feature provides a fixed duty cycle and fixed period with OCHI1 window. Autorestart feature resets OCHI2 or OCLO fault after corresponding Autorestart period. The SPI fault reports are removed after a read operation: - OC bit=(OCHI1) or (OCHI2) fault - OVL bit=(OCHI1) or (OCHI2) or (OCLO) fault Overvoltage detection and active clamp The 33480 provides an active gate clamp circuit in order to limit the maximum drain to source voltage. In case of overload on an output the corresponding switch (OUT[1 to 5]) is turned off which leads to high voltage at Vbat with an inductive Vbat line. When Vbat voltage exceeds VBAT_CLAMP threshold, the fast turn-off on the corresponding output is deactivated and the drain to source voltage is limited by the active clamp circuit (VCLAMP_DS). OCHI1 OCHI2 OCLO t1 t2 time Figure 10. Double overcurrent window in Normal Mode 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 23 PROTECTION AND DIAGNOSIS FEATURES The following diagrams (9&10) describe the faults management in Normal Mode and Fail Mode . (OCHI2=1) or (OT=1) or (UV=1) or (D7=0) (OCHI1=1) or (OT=1) or (UV=1) or (D7=0) D7=0 then 1 without fault t1 (rewrite D7=1) and (t t>t2 without fault OCHI1 OCLO (t1 (OCLO=1) or (OT=1) or (UV=1) or (D7=0) Figure 11. Faults management in Normal Mode (for OUT[1:5] only) 33480 24 Analog Integrated Circuit Device Data Freescale Semiconductor PROTECTION AND DIAGNOSIS FEATURES (external_ON=0) (OT=1) or (OCHI1=1) OFF-latched State (OT=1) (OT=1) (external_ON=0) (external_ON=1) (t>tOCHI1) and (autorestart=0) (t>tOCHI2) and (autorestart=0) OFF out: OFF autorestart=0 OCHI1 out: external (UV=1) (UV=1) and (external_on=1) OCHI2 out: external (t>tOCHI1_AUTO) and (autorestart=1) OCLO out: external (t>tautorestart) (UV*=0) and (UV=1) or (OCHI2=1) (OCLO=1) or (UV=1) (external_ON=0) OFF Autorestart out: OFF autorestart=1 (external_ON=0) 1.4 sec min external external_ON external: IGN, Flasher external_ON: IGN_ON, Flasher_ON Note: * See Autorestart strategy chapter. Figure 12. Faults management in Fail Mode (for OUT[1:5] only) Diagnosis Open Load The 33480 provides open load detection for each output (OUT1:OUT5 ) when the output terminal is in the ON state. Open load detection levels can be chosen by SPI to detect a standard bulb, a Xenon bulb for OUT2 only, or LEDs (OLLED bit). Open load for LEDs only is detected during each regular switch-off transition for minimum 200s (PWM depending D[6:0] bits <> 7F) or periodically each t OLLED (fully-on, D[6:0]=7F). To detect OLLED in fully on state, the output must be on at least t OLLED. When an open load has been detected, the output stays ON. To delatch the diagnosis, the condition should be removed and SPI read operation is needed (OL bit). In case of Power on Reset on Vbat, the fault will be reset. Current Sense The 33480 diagnosis for load current (OUT1:6) is done using the current sense (CSNS) terminal connected to an external resistor. The routing of the current sense sources is SPI programmable (MUX[2,0] bits). 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 25 PROTECTION AND DIAGNOSIS FEATURES The current recopy feature for OUT1:5 is disabled during high overcurrent shutdown phase (t2) and is only enabled during low overcurrent shutdown threshold. The current recopy output delivers current only during ON time of the output switch without overshoot (aperiodic settling). The current recopy is not active in Fail Mode. TEMPERATURE PREWARNING The 33480 provides a temperature prewarning reported via SPI (OTW bit) in Normal Mode. The information is latched. To delatch, a read SPI command is needed. In case of Power on Reset, the fault will be reset. external MOSFET (OUT6) can be controlled by SPI if Vcc remains and is above to VCCUV. The fault is reported to UVF bit (OD13). To delatch the fault, the undervoltage condition should be removed and: * The bit D7 must be rewritten to logic [1] in Normal Mode. Application of OCHI window depends on toggling or not toggling D7 bit. When the fault is delatched, the 33480 returns in the configuration it was just before the failure. * If the device was in Fail mode, the fault will be delatched by the Autorestart feature periodically. In case of VBAT The 33480 provides the status of the FLASHER, IGN, and CLOCK terminals via SPI in real time and in Normal Mode. LOSS OF VCC (DIGITAL LOGIC SUPPLY LINE) During loss of VCC (VCC < VCCUV ) and with wake=1, the 33480 is switched automatically into Fail mode (no deglich time). The external SMART MOSFET is OFF. All SPI registers are reset and must be reprogrammed when Vcc goes above VCCUV. FAILURE HANDLING STRATEGY A highly sophisticated failure handling strategy enables light functionality even in case of failures inside the component or the light module. Components are protected against: * * * Reverse Polarity Loss of Supply Lines Fatal Mistreatment of Logic I/O Terminals LOSS OF GROUND (GND) During loss of ground, the 33480 cannot operate the loads (the outputs (1:5) are switched OFF) but is not destroyed by the operating condition. Current limit resistors in the digital input lines protect the digital supply against excessive current (1kohm typical). The state of the external smart power switch controlled by FET out is not guaranteed and the state of external smart MOS is defined with external termination resistor. REVERSE POLARITY PROTECTION ON VBAT In case of permanently reverse polarity operation, the output transistors are turned ON (Rsd) to prevent thermal overload and no protections are available. External diode on Vcc is necessary in order to not destroy the 33480 in case of reverse polarity. In case of negative transients on the VBAT line (per ISO 7637), the VCC line is still operating, while the VBAT line is negative. Therefore, the device is protected against latchup. FATAL MISTREATMENT OF LOGIC I / O TERMINALS The digital I / Os are protected against fatal mistreatment by signal plausibility check according to Table 6. Table 6. Logic I / O Plausibility Check Input / Output LIMP (PWM) CLOCK SPI (MOSI, SCLK, CS) Signal Check Strategy Debounce for 10 ms Frequency range (bandpass filter) WD, D10 bit internal toggle LOSS OF SUPPLY LINES The 33480 is protected against loss of any supply line. The detection of the supply line failure is provided inside the device itself. LOSS OF VBAT During undervoltage of VBAT (VBATPOR 26 Analog Integrated Circuit Device Data Freescale Semiconductor PROTECTION AND DIAGNOSIS FEATURES the bit D7 defines the outputs state. In case of SPI failure, the 33480 is switched into Fail mode (see Fig13). WD Bit D10 0 1 timeout 75ms window watchdog 75ms window watchdog Fail Mode activation Figure 13. Watchdog window 0 D10 is toggled after the window watchdog 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 27 FUNCTIONAL DESCRIPTION PROTECTION AND DIAGNOSIS FEATURES FUNCTIONAL DESCRIPTION SERIAL INPUT COMMUNICATION SPI communication is accomplished using 16-bit messages. A message is transmitted by the master starting with the MSB, D15, and ending with the LSB, D0. Each incoming command message on the SI terminal can be interpreted using the bit assignment described in Table 7. The 5 bits D15 : D11, called register address bits, are used to select the command register. Bit D10 is the watchdog bit. The remaining 10 bits, D9 : D0, are used to configure and control the output and its protection features. Multiple messages can be transmitted in succession to accommodate those applications where daisy chaining is desirable or to confirm transmitted data as long as the messages are all multiples of 16 bits. Any attempt made to latch in a message that is not 16 bits will be ignored. All SPI registers are reset (all bit equal 0) in case of RSTB equal 0 or fail mode (Fail=1). Table 7. SI Message Bit Assignment Bit Sig MSB SI Msg Bit D15 : D11 D10 LSB D9 : D0 Message Bit Description Register address bits. Watchdog in: toggled to satisfy watchdog requirements. Used to configure inputs, outputs, device protection features, and SO status content. DEVICE REGISTER ADDRESSING The register addresses (D15 : D11) and the impact of the serial input registers on device operation are described in this section. Table 8 summarizes the SI registers. Table 8. Serial Input Address and Configuration Bit Map SI Register Initialization Config OL Unused Unused Control OUT1 Control OUT2 Control OUT3 Control OUT4 Control OUT5 Control External Switch RESET SI Address D15 D14 D13 D12 D11 D10 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 1 1 1 0 0 0 0 0 0 0 1 1 0 0 1 1 0 1 1 0 0 0 1 0 1 1 0 1 0 1 WD WD WD WD D9 0 0 0 0 D8 0 0 0 0 D7 0 0 0 0 ONoff ONoff ONoff ONoff ONoff D6 PWM sync 0 0 0 PWM6 PWM6 PWM6 PWM6 PWM6 SI Data D5 Xenon 0 0 0 PWM5 PWM5 PWM5 PWM5 PWM5 D4 MUX2 D3 MUX1 D2 MUX0 D1 SOA1 D0 SOA0 OLLED5 OLLED4 OLLED3 OLLED2 OLLED1 0 0 PWM4 PWM4 PWM4 PWM4 PWM4 0 0 PWM3 PWM3 PWM3 PWM3 PWM3 0 0 PWM2 PWM2 PWM2 PWM2 PWM2 0 0 PWM1 PWM1 PWM1 PWM1 PWM1 0 0 PWM0 PWM0 PWM0 PWM0 PWM0 WD Phase2 Phase1 WD Phase2 Phase1 WD Phase2 Phase1 WD Phase2 Phase1 WD Phase2 Phase1 0 X 1 X 1 X 1 X 0 X WD Phase2 Phase1 0 0 0 ONoff 0 PWM6 0 PWM5 0 PWM4 0 PWM3 0 PWM2 0 PWM1 0 PWM0 0 Note: testmode address used only by FSL is D[15:11]=01111 with RSTB voltage higher than 8V typ. ADDRESS 00000 -- INITIALIZATION The Initialization register is used to read the various statuses, choose one of the six outputs current recopy, load the H7 bulbs profile for OUT2 only, and synchronize the switching phases between different corner light devices. The register bits D1 and D0 determine the content of the 16 bits of the next SO data. (Refer to the section entitled Serial Output Communication (Device Status Return Data) beginning on page 30.) Table 9 describes the register of initialization. 33480 28 Analog Integrated Circuit Device Data Freescale Semiconductor FUNCTIONAL DESCRIPTION PROTECTION AND DIAGNOSIS FEATURES The watchdog timeout is specified by t WDTO parameter. As long as the WD bit (D10) of an incoming SPI message is toggled within the minimum watchdog timeout period (WDTO), the device will operate normally. If an internal watchdog timeout occurs before the WD bit is toggled, the device will revert to Fail mode. All registers are cleared. To exit the Fail mode, send valid SPI communication with WD bit = 1. Table 9. Initialization Register SI Address D15 0 D14 0 D13 0 D12 0 D11 0 D10 WD D9 0 D8 0 D7 0 D6 PWM sync SI Data D5 Xenon D4 MUX2 D3 MUX1 D2 MUX0 D1 SOA1 D0 SOA0 x = Don't care D6 (PWM sync) = 0, No synchronization D6 (PWM sync) = 1, Synchronization on CSB positive edge D5 (Xenon) = 0, Xenon D5 (Xenon) = 1, H7 Bulb D4, D3, D2 (MUX2, MUX1, MUX0) = 000, No current sense D4, D3, D2 (MUX2, MUX1, MUX0) = 001, OUT1 current sense D4, D3, D2 (MUX2, MUX1, MUX0) = 010, OUT2 current sense D4, D3, D2 (MUX2, MUX1, MUX0) = 011, OUT3 current sense D4, D3, D2 (MUX2, MUX1, MUX0) = 100, OUT4 current sense D4, D3, D2 (MUX2, MUX1, MUX0) = 101, OUT5 current sense D4, D3, D2 (MUX2, MUX1, MUX0) = 110, External Switch current sense D4, D3, D2 (MUX2, MUX1, MUX0) = 111, No current sense ADDRESS 00001 -- CONFIGURATION OL The Configuration OL register is used to enable the open load detection for LEDs in Normal Mode (OLLEDn in Table 8, page 28). When bit D0 is set to logic [1], the open load detection circuit for LED is activated for output 1. When bit D0 is set to logic [0], open load detection circuit for standard bulbs is activated for output 1. Bit D7 at logic [1] turns ON OUT1. OUT1 is turned OFF with bit D7 at logic [0]. This register allows the master to control the duty cycle and the switching phases of OUT1. The duty cycle resolution is given by bits D6 : D0. D7 = 0, D6 : D0 = XX output OFF. D7 = 1, D6 : D0 = 00 output ON during 1/128. D7 = 1, D6 : D0 = 1A output ON during 27/128 on PWM period. D7 = 1, D6 : D0 = 7F output continuous ON (no PWM). ADDRESS 00010 This register is not used. ADDRESS 00011 This register is not used. ADDRESS 01010 -- CONTROL OUT2 Same description as OUT1. ADDRESS 01001 -- CONTROL OUT1 Bits D9 and D8 control the switching phases as shown in Table 10. Table 10. Switching Phases D9 : D8 00 01 10 11 PWM Phase 0 90 180 270 ADDRESS 011111 -- CONTROL OUT3 Same description as OUT1. ADDRESS 01100 -- CONTROL OUT4 Same description as OUT1. ADDRESS 01101 -- CONTROL OUT5 Same description as OUT1. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 29 FUNCTIONAL DESCRIPTION PROTECTION AND DIAGNOSIS FEATURES ADDRESS 01110 -- CONTROL EXTERNAL SWITCH Same description as OUT1. terminal is tri-stated and the fault status register is now able to accept new fault status information. The output status register correctly reflects the status of the Initialization-selected register data at the time that the CS is pulled to a logic [0] during SPI communication and / or for the period of time since the last valid SPI communication, with the following exceptions: * The previous SPI communication was determined to be invalid. In this case, the status will be reported as though the invalid SPI communication never occurred. * Battery transients below 6.0 V, resulting in an undervoltage shutdown of the outputs, may result in incorrect data loaded into the status register. ADDRESS 01111 -- TEST MODE This register is reserved for test and is not available with SPI during normal operation. SERIAL OUTPUT COMMUNICATION (DEVICE STATUS RETURN DATA) When the CS terminal is pulled low, the output register is loaded. Meanwhile, the data is clocked out MSB first as the new message data is clocked into the SI terminal. The first 16 bits of data clocking out of the SO, and following a CS transition, is dependant upon the previously written SPI word (SOA1 and SOA0 defined in the last SPI initialization word). Any bits clocked out of the SO terminal after the first 16 will be representative of the initial message bits clocked into the SI terminal since the CS terminal first transitioned to a logic [0]. This feature is useful for daisy chaining devices. A valid message length is determined following a CS transition of logic [0] to logic [1]. If the message length is valid, the data is latched into the appropriate registers. A valid message length is a multiple of 16 bits. At this time, the SO SERIAL OUTPUT BIT ASSIGNMENT The contents of bits OD15 : OD0 depend on bits D1: D0 from the most recent initialization command SOA[1:0] (refer to Table 8, page 28), as explained in the paragraphs that follow. The register bits are reset by a read operation and also if the fault is removed. Table 11 summarizes the SO register content. Bit OD10 reflects Normal mode (NM). Table 11. Serial Output Bit Map Description Status / Mode Output Status Overload Status Device Status Test Mode Reset Previous SI Data SO A1 0 0 1 1 X SO OD15 OD14 OD13 OD12 OD11 OD10 OD9 A0 0 1 0 1 X 0 0 1 1 0 0 1 0 1 0 UVF UVF UVF UVF 0 OTW OTW OTW OTW 0 OTS OTS OTS OTS 0 NM NM NM NM 0 OL5 OC5 0 0 1 OD8 OVL5 OTS5 OV 0 0 SO Data OD7 OL4 OC4 X 0 0 OD6 OVL4 OTS4 X 0 0 OD5 OL3 OC3 X 0 0 OD4 OVL3 OTS3 RC 0 0 OD3 OL2 OC2 0 0 0 OD2 OVL2 OTS2 FLASHER OD1 OL1 OC1 IGN pin 0 0 OD0 OVL1 OTS1 CLOCK pin 0 0 fail 0 0 33480 30 Analog Integrated Circuit Device Data Freescale Semiconductor FUNCTIONAL DESCRIPTION PROTECTION AND DIAGNOSIS FEATURES PREVIOUS ADDRESS SOA[1:0] = 00 If the previous two LSBs are 00, bits OD15 : OD0 reflect the output status (Table 12). Table 12. Output Status OD15 0 OD14 0 OD13 UVF OD12 OTW OD11 OTS OD10 NM OD9 OL5 OD8 OVL5 OD7 OL4 OD6 OVL4 OD5 OL3 OD4 OVL3 OD3 OL2 OD2 OVL2 OD1 OL1 OD0 OVL1 OD13 (UVF) = Undervoltage Flag on Vbat OD12 (OTW) = Overtemperature Prewarning Flag OD11 (OTS) = Overtemperature Flag for all outputs OD10 (NM) = Normal mode Note OD9, OD7, OD5, OD3, OD1 (OL5, OL4, OL3, OL2, OL1) = Open Load Flag at Outputs 5 through 1, respectively. OD8, OD6, OD4, OD2, OD0 (OVL5, OVL4, OVL3, OVL2, OVL1) = Overload Flag for Outputs 5 through 1, respectively.This corresponds to overtemperature or OCHI or OCLO faults. A logic [1] at bits OD9:OD0 indicates a fault. If there is no fault, bits OD9:OD0 are logic [0]. OVL=OCHI1+OCHI2+OCLO PREVIOUS ADDRESS SOA[1:0] = 01 If the previous two LSBs are 01, bits OD15 :O D0 reflect reflect the temperature status (Table 13). Table 13. Overload Status OD15 0 OD14 1 OD13 UVF OD12 OTW OD11 OTS OD10 NM OD9 OC5 OD8 OTS5 OD7 OC4 OD6 OTS4 OD5 OC3 OD4 OTS3 OD3 OC2 OD2 OTS2 OD1 OC1 OD0 OTS1 OD13 (UVF) = Undervoltage Flag on Vbat OD12 (OTW) = Overtemperature Prewarning Flag OD11 (OTS) = Overtemperature Flag for all outputs OD10 (NM) = Normal mode Note OD9, OD7, OD5, OD3, OD1 (OC5, OC4, OC3, OC2, OC1) = High Overcurrent Shutdown Flag for Outputs 5 through 1, respectively OD8, OD6, OD4, OD2, OD0 (OTS5, OTS4, OTS3, OTS2, OTS1) = Overtemperature Flag for Outputs 5 through 1, respectively A logic [1] at bits OD9:OD0 indicates a fault. If there is no fault, bits OD9:OD0 are logic [0]. OC=OCHI1+OCHI2 PREVIOUS ADDRESS SOA[1:0] = 10 If the previous two LSBs are 01, bits OD15 : OD0 reflect the status of the 33480 (Table 14). Table 14. Device Status OD15 1 OD14 0 OD13 UVF OD12 OTW OD11 OTS OD10 NM OD9 0 OD8 0V OD7 X OD6 X OD5 X OD4 RC OD3 0 OD2 OD1 OD0 FLASH IGN pin CLOCK ER pin fail OD13 (UVF) = Undervoltage Flag on Vbat OD12 (OTW) = Overtemperature Prewarning Flag OD11 (OTS) = Overtemperature Flag for all outputs OD10 (NM) = Normal mode OD4 (RC) = Logic [0] indicates a Front Corner Light Switch. Logic [1] indicates a Rear Corner Light Switch OD2 (FLASHER pin) = Indicates the FLASHER terminal state in real time OD1 (IGN pin) = Indicates the IGN terminal state in real time OD0 (CLOCK fail) = Logic [1], which indicates a clock failure OD8 (Overvoltage) = Overvoltage Flag on Vbat in real time PREVIOUS ADDRESS SOA[1:0] = 11 Null Data. No previous register Read Back command received, so bits OD9 : OD0 are null. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 31 TYPICAL APPLICATION PROTECTION AND DIAGNOSIS FEATURES TYPICAL APPLICATION Figure 14 below shows full vehicle light functionality, including fog lights, battery redundancy concept, light substitution mode, and Fail mode. g in rk Pa e Li gh ig ht Lo Be w am F l Be as am Pa her rk in g Li gh t e ar t Sp gh Li g Fo eam B h ig am H Be er w Lo a s h Fl ht g Li Sp ar Fo H g CP 100nF VBAT MOSI, MISO, SCLK CP CS MC33480 Smart Corner Light Switch (Front Left) CS CLOCK RSTB IGN LIMP FLASHER CSNS CLOCK RSTB IGN LIMP FLASHER CSNS MC33480 Smart Corner Light Switch (Front Right) VBAT 100nF VCC VCC t gh t Li gh og Li t e rF riv igh ea R rD eL t h ea s R cen Lig Li op er h St as Fl ht g Li il Ta R ea rF ea og rD Li Li gh ce riv t ne St se Lig op L ht ig Fl Lig ht as ht Ta her il Li gh t R 100nF CP 100nF MC33481 VBAT CS CS CP CLOCK RSTB IGN LIMP FLASHER STOP CSNS CLOCK RSTB IGN LIMP FLASHER STOP CSNS MC33481 VBAT Smart Corner Light Switch (Rear Left) VCC Smart Corner Light Switch (Rear Right) VCC Microcontroller Watchdog VCC (5.0 V) WD (5.0 V) V Figure 14. Typical Application I ii S Li h Fl h V 33480 32 Analog Integrated Circuit Device Data Freescale Semiconductor TYPICAL APPLICATION PROTECTION AND DIAGNOSIS FEATURES EMC & EMI PERFORMANCES The 33480 must pass successfully the Class5 of the norm CISPR25. The evaluation will be done on the Freescale board rev1.1. Conditions to be defined. RELIABILITY TESTS See document SCLS_reliability test spec_V22.doc, RevisionV2.2, Date September,23rd,2005. 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 33 PACKAGING PACKAGING DIMENSIONS PACKAGING PACKAGING DIMENSIONS PNA SUFFIX 24-TERMINAL PQFN PLASTIC PACKAGE 98ARL10596D ISSUE B 33480 34 Analog Integrated Circuit Device Data Freescale Semiconductor PACKAGING PACKAGING DIMENSIONS 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 35 PACKAGING PACKAGING DIMENSIONS 33480 36 Analog Integrated Circuit Device Data Freescale Semiconductor PACKAGING PACKAGING DIMENSIONS 33480 Analog Integrated Circuit Device Data Freescale Semiconductor 37 REVISION HISTORY REVISION HISTORY Revision 2.0 Date 12/2005 Description of Changes * * Implemented Revision History page Converted to Freescale format 33480 38 Analog Integrated Circuit Device Data Freescale Semiconductor How to Reach Us: Home Page: www.freescale.com E-mail: support@freescale.com USA/Europe or Locations Not Listed: Freescale Semiconductor Technical Information Center, CH370 1300 N. Alma School Road Chandler, Arizona 85224 +1-800-521-6274 or +1-480-768-2130 support@freescale.com Europe, Middle East, and Africa: Freescale Halbleiter Deutschland GmbH Technical Information Center Schatzbogen 7 81829 Muenchen, Germany +44 1296 380 456 (English) +46 8 52200080 (English) +49 89 92103 559 (German) +33 1 69 35 48 48 (French) support@freescale.com Japan: Freescale Semiconductor Japan Ltd. Headquarters ARCO Tower 15F 1-8-1, Shimo-Meguro, Meguro-ku, Tokyo 153-0064 Japan 0120 191014 or +81 3 5437 9125 support.japan@freescale.com Asia/Pacific: Freescale Semiconductor Hong Kong Ltd. Technical Information Center 2 Dai King Street Tai Po Industrial Estate Tai Po, N.T., Hong Kong +800 2666 8080 support.asia@freescale.com For Literature Requests Only: Freescale Semiconductor Literature Distribution Center P.O. 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Freescale Semiconductor makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Freescale Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. "Typical" parameters that may be provided in Freescale Semiconductor data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including "Typicals", must be validated for each customer application by customer's technical experts. Freescale Semiconductor does not convey any license under its patent rights nor the rights of others. Freescale Semiconductor products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Freescale Semiconductor product could create a situation where personal injury or death may occur. Should Buyer purchase or use Freescale Semiconductor products for any such unintended or unauthorized application, Buyer shall indemnify and hold Freescale Semiconductor and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that Freescale Semiconductor was negligent regarding the design or manufacture of the part. FreescaleTM and the Freescale logo are trademarks of Freescale Semiconductor, Inc. All other product or service names are the property of their respective owners. (c) Freescale Semiconductor, Inc., 2005. All rights reserved. MC33480 Rev 2.0 1/2006 |
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