Freescale Semiconductor Technical Data Document Number: MC33886 Rev 8.0, 2/2007 5.0 A H-Bridge 33886 The 33886 is a monolithic H-Bridge ideal for fractional horsepower DC-motor and bi-directional thrust solenoid control. The IC incorporates internal control logic, charge pump, gate drive, and low RDS(ON) MOSFET output circuitry. The 33886 is able to control continuous inductive DC load currents up to 5.0 A. Output loads can be pulse width modulated (PWM-ed) at frequencies up to 10 kHz. A Fault Status output reports undervoltage, short circuit, and overtemperature conditions. Two independent inputs control the two half-bridge totem-pole outputs. Two disable inputs force the H-Bridge outputs to tri-state (exhibit high impedance). The 33886 is parametrically specified over a temperature range of -40C TA 125C, 5.0 V V+ 28 V. The IC can also be operated up to 40 V with derating of the specifications. The IC is available in a surface mount power package with exposed pad for heatsinking. Features * 5.0 V to 40 V Continuous Operation * 120 m RDS(ON) H-Bridge MOSFETs * TTL / CMOS Compatible Inputs * PWM Frequencies up to 10 kHz * Active Current Limiting via Internal Constant OFF-Time PWM (with Temperature-Dependent Threshold Reduction) * Output Short Circuit Protection * Undervoltage Shutdown * Fault Status Reporting * Pb-Free Packaging Designated by Suffix Code VW H-BRIDGE VW SUFFIX (PB-FREE) DH SUFFIX 98ASH70702A 20-PIN HSOP ORDERING INFORMATION Device MC33886DH/R2 Temperature Range (TA) Package - 40C to 125C 20 HSOP MC33886VW/R2 V+ 33886 5.0 V CCP V+ OUT1 MCU IN FS OUT IN1 OUT OUT IN2 D1 PGND OUT D2 AGND MOTOR OUT2 Figure 1. 33886 Simplified Application Diagram Freescale Semiconductor, Inc. reserves the right to change the detail specifications, as may be required, to permit improvements in the design of its products. (c) Freescale Semiconductor, Inc., 2007. All rights reserved. INTERNAL BLOCK DIAGRAM INTERNAL BLOCK DIAGRAM C VPWR CCP V+ CP Charge Pump 80 A 80 uA (each) OUT1 IN1 IN2 D1 D2 Current Limit, Current Limit, Overcurrent Short Circuit Sense Sense Circuit Circuit 5.0 V Regulator Gate Drive OUT2 25 uA 25 A Control Logic OverOvertemperature temperature Undervoltage FS AGND PGND Figure 2. 33886 Simplified Internal Block Diagram 33886 2 Analog Integrated Circuit Device Data Freescale Semiconductor PIN CONNECTIONS PIN CONNECTIONS AGND 1 20 DNC FS 2 19 IN2 IN1 3 18 D1 V+ 4 17 CCP V+ 5 16 V+ OUT1 6 15 OUT2 OUT1 7 14 OUT2 DNC 8 13 D2 PGND 9 12 PGND PGND 10 11 PGND Figure 3. 33886 Pin Connections Table 1. 33886 Pin Definitions A functional description of each pin can be found in the Functional Pin Description section beginning on page 15. Pin Number Pin Name Formal Name 1 AGND Analog Ground 2 FS Fault Status for HBridge 3 IN1 Logic Input Control 1 4, 5, 16 V+ 6, 7 OUT1 H-Bridge Output 1 8, 20 DNC Do Not Connect 9 -12 PGND Power Ground 13 D2 Disable 2 14, 15 OUT2 H-Bridge Output 2 17 CCP 18 D1 Disable 1 19 IN2 Logic Input Control 2 Definition Low-current analog signal ground. Open drain active Low Fault Status output requiring a pull-up resistor to 5.0 V. True logic input control of OUT1 (i.e., IN1 logic High = OUT1 logic High). Positive Power Supply Positive supply connections. Output 1 of H-Bridge. Either do not connect (leave floating) or connect these pins to ground in the application. They are test mode pins used in manufacturing only. Device high-current power ground. Active Low input used to simultaneously tri-state disable both H-Bridge outputs. When D2 is logic Low, both outputs are tri-stated. Output 2 of H-Bridge. Charge Pump Capacitor External reservoir capacitor connection for internal charge pump capacitor. Active High input used to simultaneously tri-state disable both H-Bridge outputs. When D1 is logic High, both outputs are tri-stated. True logic input control of OUT2 (i.e., IN2 logic High = OUT2 logic High). 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 3 ELECTRICAL CHARACTERISTICS MAXIMUM RATINGS ELECTRICAL CHARACTERISTICS 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. Rating Symbol Value Unit V+ 40 V VIN -0.1 to 7.0 V V FS 7.0 V IOUT 5.0 A VESD1 2000 (6) VESD2 200 Human Body Model (4) VESD1 2000 Machine Model (5) VESD2 200 TSTG -65 to 150 C TA -40 to 125 C TJ -40 to 150 C TPPRT Note 8. C RJB ~5.0 C/W Supply Voltage Input Voltage (1) FS Status Output (2) Continuous Current (3) ESD Voltage for DH Package Human Body Model V (4) Machine Model (5) ESD Voltage for VW Package V Storage Temperature Ambient Operating Temperature (7) Operating Junction Temperature Peak Package Reflow Temperature During Reflow (8) (9) , Approximate Junction-to-Board Thermal Resistance (and Package Dissipation = 6.0 W) (10) Notes 1. 2. 3. 4. Exceeding the input voltage on IN1, IN2, D1, or D2 may cause a malfunction or permanent damage to the device. Exceeding the pull-up resistor voltage on the open drain FS pin may cause permanent damage to the device. Continuous current capability so long as junction temperature is 150C. ESD1 testing is performed in accordance with the Human Body Model (CZAP = 100 pF, RZAP = 1500 ). 5. ESD2 testing is performed in accordance with the Machine Model (CZAP = 200 pF, RZAP = 0 ). 6. All pins are capable of Human Body Model ESD voltages of 2000 V with two exceptions pertaining only to the DH suffix package: (1) D2 to PGND is capable of 1500 V and (2) OUT1 to AGND is capable of 1000 V. The limiting factor is junction temperature, taking into account the power dissipation, thermal resistance, and heatsinking. Pin 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. Freescale's Package Reflow capability meets Pb-free requirements for JEDEC standard J-STD-020C. For Peak Package Reflow Temperature and Moisture Sensitivity Levels (MSL), Go to www.freescale.com, search by part number [e.g. remove prefixes/suffixes and enter the core ID to view all orderable parts. (i.e. MC33xxxD enter 33xxx), and review parametrics. Exposed heatsink pad plus the power and ground pins comprise the main heat conduction paths. The actual RJB (junction-to-PC board) values will vary depending on solder thickness and composition and copper trace. 7. 8. 9. 10. 33886 4 Analog Integrated Circuit Device Data Freescale Semiconductor ELECTRICAL CHARACTERISTICS STATIC ELECTRICAL CHARACTERISTICS STATIC ELECTRICAL CHARACTERISTICS Table 3. Static Electrical Characteristics Characteristics noted under conditions 5.0 V V+ 28 V and -40C TA 125C unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25C under nominal conditions unless otherwise noted. Characteristic Symbol Min Typ Max Unit V+ 5.0 - 40 V POWER SUPPLY Operating Voltage Range (11) Standby Supply Current IQ (standby) VEN = 5.0 V, IOUT = 0 A mA - - 20 Threshold Supply Voltage Switch-OFF Switch-ON Hysteresis V+(thres-OFF) 4.15 4.4 4.65 V+(thres-ON) 4.5 4.75 5.0 V V V+(hys) 150 - - mV 3.35 - - - - 20 VIH 3.5 - - VIL - - 1.4 VHYS 0.7 1.0 - -200 -80 - - 25 100 CHARGE PUMP Charge Pump Voltage VCP - V+ V+ = 5.0 V 8.0 V V+ 40 V V CONTROL INPUTS Input Voltage (IN1, IN2, D1, D2) Threshold High Threshold Low Hysteresis Input Current (IN1, IN2, D1) (12) V D2 Input Current (13) V D2 = 5.0 V A IIN VIN = 0 V A I D2 Notes 11. Specifications are characterized over the range of 5.0 V V+ 28 V. Operation > 28 V will cause some parameters to exceed listed min/max values. Refer to typical operating curves to extrapolate values for operation > 28 V but 40 V. 12. Inputs IN1, IN2, and D1 have independent internal pull-up current sources. 13. The D2 input incorporates an active internal pull-down current sink. 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 5 ELECTRICAL CHARACTERISTICS STATIC ELECTRICAL CHARACTERISTICS Table 3. Static Electrical Characteristics Characteristics noted under conditions 5.0 V V+ 28 V and -40C TA 125C unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25C under nominal conditions unless otherwise noted. Characteristic Symbol Min Typ Max Unit POWER OUTPUTS (OUT1, OUT2) Output-ON Resistance (14) RDS(ON) m 5.0 V V+ 28 V, TJ = 25C - 120 - 8.0 V V+ 28 V, TJ = 150C - - 225 5.0 V V+ 8.0 V, TJ = 150C - - 300 5.2 6.5 7.8 Active Current Limiting Threshold (via Internal Constant OFF-Time PWM) (15) ILIM High-Side Short Circuit Detection Threshold ISCH 11 - - A Low-Side Short Circuit Detection Threshold ISCL 8.0 - - A VOUT = V+ - 100 200 VOUT = GND - 30 60 - - 2.0 TLIM 175 - - THYS - 15 - Leakage Current (16) A A IOUT(leak) Output FET Body Diode Forward Voltage Drop (17) VF IOUT = 3.0 A V Switch-OFF C Thermal Shutdown Hysteresis FAULT STATUS (18) Fault Status Leakage Current (19) Fault Status Set Voltage I FS = 300 A A I FS(leak) V FS = 5.0 V - (20) - 10 V FS(LOW) V - - 1.0 Notes 14. Output-ON resistance as measured from output to V+ and ground. 15. Product with date codes of December 2002, week 51, will exhibit the values indicated in this table. Product with earlier date codes may exhibit a minimum of 6.0 A and a maximum of 8.5 A. 16. Outputs switched OFF with D1 or D2. 17. Parameter is guaranteed by design but not production tested. 18. Fault Status output is an open drain output requiring a pull-up resistor to 5.0 V. 19. Fault Status Leakage Current is measured with Fault Status High and not set. 20. Fault Status Set Voltage is measured with Fault Status Low and set with I FS = 300 A. 33886 6 Analog Integrated Circuit Device Data Freescale Semiconductor ELECTRICAL CHARACTERISTICS DYNAMIC ELECTRICAL CHARACTERISTICS DYNAMIC ELECTRICAL CHARACTERISTICS Table 4. Dynamic Electrical Characteristics Characteristics noted under conditions 5.0 V V+ 28 V and -40C TA 125C unless otherwise noted. Typical values noted reflect the approximate parameter mean at TA = 25C under nominal conditions unless otherwise noted. Characteristic Symbol Min Typ Max Unit f PWM - - 10 kHz f MAX - - 20 kHz - - 18 TIMING CHARACTERISTICS PWM Frequency (21) Maximum Switching Frequency During Active Current Limiting Output ON Delay (23) (22) Output OFF Delay (23) s t d (OFF) V+ = 14 V Output Rise and Fall Time s t d (ON) V+ = 14 V (24) - - 18 2.0 5.0 8.0 s tf , t r V+ = 14 V, IOUT = 3.0 A Output Latch-OFF Time ta 15 20.5 26 s Output Blanking Time tb 12 16.5 21 s Output FET Body Diode Reverse Recovery Time (25) trr 100 - - ns t d (disable) - - 8.0 s t FAULT - 4.0 - s t pod - 1.0 5.0 ms Disable Delay Time (26) Short Circuit / Overtemperature Turn-OFF Time (27) Power-OFF Delay Time Notes 21. The outputs can be PWM controlled from an external source. This is typically done by holding one input high while applying a PWM pulse train to the other input. The maximum PWM frequency obtainable is a compromise between switching losses and switching frequency. Refer to Typical Switching Waveforms, Figures 10 through 17, pp. 10-11. 22. The Maximum Switching Frequency during active current limiting is internally implemented. The internal control produces a constant OFF-time PWM of the output. The output load current effects the Maximum Switching Frequency. 23. Output Delay is the time duration from the midpoint of the IN1 or IN2 input signal to the 10% or 90% point (dependent on the transition direction) of the OUT1 or OUT2 signal. If the output is transitioning High-to-Low, the delay is from the midpoint of the input signal to the 90% point of the output response signal. If the output is transitioning Low-to-High, the delay is from the midpoint of the input signal to the 10% point of the output response signal. See Figure 4, page 8. 24. Rise Time is from the 10% to the 90% level and Fall Time is from the 90% to the 10% level of the output signal. See Figure 6, page 8. 25. Parameter is guaranteed by design but not production tested. 26. Disable Delay Time is the time duration from the midpoint of the D (disable) input signal to 10% of the output tri-state response. See Figure 5, page 8. 27. Increasing currents will become limited at ILIM. Hard shorts will breach the ISCH or ISCL limit, forcing the output into an immediate tristate latch-OFF. See Figures 8 and 9, page 9. Active current limiting will cause junction temperatures to rise. A junction temperature above 160C will cause the active current limiting to progressively "fold-back" (or decrease) to 2.5 A typical at 175C where thermal latch-OFF will occur. See Figure 7, page 8. 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 7 TIMING DIAGRAMS VIN1, IN2 (V) TIMING DIAGRAMS 5.0 50% VOUT1, 2 (V) 0 50% td(OFF) td(ON) VPWR 90% 10% 0 TIME Figure 4. Output Delay Time 5.0 V 0V 0 VOUT1, 2 (V) Figure 5. Disable Delay Time V PWR tf tr 90% 90% 10% 10% 0 IIMAX CURRENT (A) (A) LIM, IOUTPUT LIM, CURRENT Figure 6. Output Switching Time 6.5 6.6 2.5 Thermal Shutdown 160 175 T J, JUNCTION TEMPERATURE (o C) Figure 7. Active Current Limiting Versus Temperature (Typical) 33886 8 Analog Integrated Circuit Device Data Freescale Semiconductor TIMING DIAGRAMS Diode Reverse FS, SF LOGIC OUT D2, LOGIC IN D1, LOGIC IN INn, LOGIC IN IOUT , CURRENT (A) (A) CURRENT IILOAD ,, OUTPUT OUT Spikes LoadRecovery Capacitance and/or Diode Reverse Recovery Spikes 8.0 ISCL Short Circuit Detect Threshold Typ. Short Ckt. Detect Threshold 6.5 Typical Current Threshold Typ. Current Limit Limiting Threshold for Low-Side FETs PWM Active Current Current Limiting Limiting (See Figure 6) 7) (SeeFigure (See 7) Hard and Latch-OFF HardShort ShortDetect Detect and Latch-Off 0 [1] [0] IN1 IN1IN2 IN2 or IN2 IN2 IN1 OR IN2OR orIN2 IN1 IN1 IN2 IN2 or OR IN1 IN1OR orIN1 IN2 IN2 [1] [0] [1] [0] [1] Outputs Outputs Tristated Tri-stated OutputsOperational Operational Outputs (perInput InputControl Control Condition) Condition) (per Outputs Tristated Tri-stated [0] TIME CURRENT ILOAD , OUTPUT IOUT , CURRENT (A) (A) Figure 8. Active Current Limiting Versus Time IShort Circuit Detect Threshold Circuit Detect Threshold Overcurrent Minimum Threshold SCL Short 8.0 ta tb Output Latch-OFF taa == Tristate Output OFFTime Time Output Blanking Time ttbb ==Current Limit Blank Time 6.5 Typical Current Typical Load LimitingPWM Waveform Current Limiting Waveform Hard Short OutputDetect Hard Short Latch-OFF Latch-Off Prevented During tb TIME Figure 9. Active Current Limiting Detail 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 9 TYPICAL SWITCHING WAVEFORMS TYPICAL SWITCHING WAVEFORMS * * * * Important For all plots, the following applies: Ch2 = 2.0 A per division LLOAD = 533 H @ 1.0 kHz LLOAD = 530 H @ 10.0 kHz RLOAD = 4.0 Output Voltage (OUT1) IOUT Output Voltage (OUT1) Input Voltage (IN1) IOUT V+=34 V Input Voltage (IN1) V+=24 V fPWM =1.0 kHz Duty Cycle=10% Figure 10. Output Voltage and Current vs. Input Voltage at V+ = 24 V, PMW Frequency of 1.0 kHz, and Duty Cycle of 10% fPWM =1.0 kHz Duty Cycle=90% Figure 12. Output Voltage and Current vs. Input Voltage at V+ = 34 V, PMW Frequency of 1.0 kHz, and Duty Cycle of 90%, Showing Device in Current Limiting Mode Output Voltage (OUT1) IOUT Output Voltage (OUT1) Input Voltage (IN1) V+=22 V IOUT Input Voltage (IN1) V+=24 V fPWM =1.0 kHz Duty Cycle=50% fPWM =1.0 kHz Duty Cycle=90% Figure 13. Output Voltage and Current vs. Input Voltage at V+ = 22 V, PMW Frequency of 1.0 kHz, and Duty Cycle of 90% Figure 11. Output Voltage and Current vs. Input Voltage at V+ = 24 V, PMW Frequency of 1.0 kHz, and Duty Cycle of 50% 33886 10 Analog Integrated Circuit Device Data Freescale Semiconductor TYPICAL SWITCHING WAVEFORMS Output Voltage (OUT1) Output Voltage (OUT1) IOUT IOUT Input Voltage (IN1) Input Voltage (IN1) V+=24 V fPWM =10 kHz V+=12 V Duty Cycle=50% Figure 14. Output Voltage and Current vs. Input Voltage at V+ = 24 V, PMW Frequency of 10 kHz, and Duty Cycle of 50% Output Voltage (OUT1) IOUT IOUT Input Voltage (IN1) Input Voltage (IN1) fPWM =10 kHz Duty Cycle=90% Figure 15. Output Voltage and Current vs. Input Voltage at V+ = 24 V, PMW Frequency of 10 kHz, and Duty Cycle of 90% Duty Cycle=50% Figure 16. Output Voltage and Current vs. Input Voltage at V+ = 12 V, PMW Frequency of 20 kHz, and Duty Cycle of 50% for a Purely Resistive Load Output Voltage (OUT1) V+=24 V fPWM =20 kHz V+=12 V fPWM =20 kHz Duty Cycle=90% Figure 17. Output Voltage and Current vs. Input Voltage at V+ = 12 V, PMW Frequency of 20 kHz, and Duty Cycle of 90% for a Purely Resistive Load 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 11 TYPICAL SWITCHING WAVEFORMS Table 5. Truth Table The tri-state conditions and the fault status are reset using D1 or D2. The truth table uses the following notations: L = Low, H = High, X = High or Low, and Z = High impedance (all output power transistors are switched off). Fault Status Flag Input Conditions Device State Output States D1 D2 IN1 IN2 FS OUT1 OUT2 Forward L H H L H H L Reverse L H L H H L H Freewheeling Low L H L L H L L Freewheeling High L H H H H H H Disable 1 (D1) H X X X L Z Z Disable 2 (D2) X L X X L Z Z IN1 Disconnected L H Z X H H X IN2 Disconnected L H X Z H X H D1 Disconnected Z X X X L Z Z D2 Disconnected X Z X X L Z Z (28) X X X X L Z Z X X X X L Z Z X X X X L Z Z Undervoltage Overtemperature (29) Short Circuit (29) Notes 28. In the case of an undervoltage condition, the outputs tri-state and the fault status is set logic Low. Upon undervoltage recovery, fault status is reset automatically or automatically cleared and the outputs are restored to their original operating condition. 29. When a short circuit or overtemperature condition is detected, the power outputs are tri-state latched-OFF independent of the input signals and the fault status flag is set logic Low. 33886 12 Analog Integrated Circuit Device Data Freescale Semiconductor ELECTRICAL PERFORMANCE CURVES ELECTRICAL PERFORMANCE CURVES 0.40 0.35 0.30 Ohms 0.25 0.20 0.15 0.10 0.05 0.0 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 Volts Figure 18. Typical High-Side RDS(ON) Versus V+ 0.13 Ohms OHMS 0.128 0.126 0.124 0.122 0.12 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 Volts VPWR Figure 19. Typical Low-Side RDS(ON) Versus V+ 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 13 ELECTRICAL PERFORMANCE CURVES 9.0 8.0 7.0 milliOHMS amperes 6.0 5.0 4.0 3.0 2.0 1.0 0.0 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 41 Volts VPWR Figure 20. Typical Quiescent Supply Current Versus V+ 33886 14 Analog Integrated Circuit Device Data Freescale Semiconductor FUNCTIONAL DESCRIPTION INTRODUCTION FUNCTIONAL DESCRIPTION INTRODUCTION Numerous protection and operational features (speed, torque, direction, dynamic braking, and PWM control), in addition to the 5.0 A current capability, make the 33886 a very attractive, cost-effective solution for controlling a broad range of fractional horsepower DC motors. A pair of 33886 devices can be used to control bipolar stepper motors in both directions. In addition, the 33886 can be used to control permanent magnet solenoids in a push-pull variable force fashion using PWM control. The 33886 can also be used to excite transformer primary windings with a switched square wave to produce secondary winding AC currents. As shown in Figure 2, Simplified Internal Block Diagram, page 2, the 33886 is a fully protected monolithic H-Bridge with Fault Status reporting. For a DC motor to run the input conditions need be as follows: D1 input logic Low, D2 input logic High, FS flag cleared (logic High), with one IN logic Low and the other IN logic High to define output polarity. The 33886 can execute dynamic braking by simultaneously turning on either both high-side MOSFETs or both low-side MOSFETs in the output H-Bridge; e.g., IN1 and IN2 logic High or IN1 and IN2 logic Low. The 33886 outputs are capable of providing a continuous DC load current of 5.0 A from a 40 V V+ source. An internal charge pump supports PWM frequencies up to 10 kHz. An external pull-up resistor is required for the open drain FS pin for fault status reporting. Two independent inputs (IN1 and IN2) provide control of the two totem-pole half-bridge outputs. Two disable inputs (D1 and D2) are for forcing the H-Bridge outputs to a high impedance state (all H-Bridge switches OFF). The 33886 has undervoltage shutdown with automatic recovery, active current limiting, output short-circuit latchOFF, and overtemperature latch-OFF. An undervoltage shutdown, output short circuit latch-OFF, or overtemperature latch-OFF fault condition will cause the outputs to turn OFF (i.e., become high impedance or tri-stated) and the fault output flag to be set Low. Either of the Disable inputs or V+ must be "toggled" to clear the fault flag. The short circuit / overtemperature shutdown scheme is unique and best described as using a junction temperaturedependent active current "fold back" protection scheme. When a short circuit condition is experienced, the current limited output is "ramped down" as the junction temperature increases above 160C, until at 175C the current has decreased to about 2.5 A. Above 175C, overtemperature shutdown (latch-OFF) occurs. This feature allows the device to remain in operation for a longer time with unexpected loads, while still retaining adequate protection for both the device and the load. FUNCTIONAL PIN DESCRIPTION POWER/ANALOG GROUNDS (PGND AND AGND) FAULT STATUS (FS) Power and analog ground pins. The power and analog ground pins should be connected together with a very low impedance connection. This pin is the device fault status output. This output is an active Low open drain structure requiring a pull-up resistor to 5.0 V. Refer to Table 5, Truth Table, page 12. POSITIVE POWER SUPPLY (V+) LOGIC INPUT 1, 2 AND DISABLE1, 2 (IN1, IN2, D1, AND D2) V+ pins are the power supply inputs to the device. All V+ pins must be connected together on the printed circuit board with as short as possible traces offering as low impedance as possible between pins. V+ pins have an undervoltage threshold. If the supply voltage drops below a V+ undervoltage threshold, the output power stage switches to a tri-state condition and the fault status flag is set and the Fault Status pin voltage switched to a logic Low. When the supply voltage returns to a level that is above the threshold, the power stage automatically resumes normal operation according to the established condition of the input pins and the fault status flag is automatically reset logic High. These pins are input control pins used to control the outputs. These pins are 5.0 V CMOS-compatible inputs with hysteresis. The IN1 and IN2 independently control OUT1 and OUT2, respectively. D1 and D2 are complimentary inputs used to tri-state disable the H-Bridge outputs. When either D1 or D2 is set (D1 = logic High or D2 = logic Low) in the disable state, outputs OUT1 and OUT2 are both tri-state disabled; however, the rest of the device circuitry is fully operational and the supply IQ (standby) current is reduced to a few milliamperes. Refer to Table 5, Truth Table, and Static Electrical Characteristics table, page 5. 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 15 FUNCTIONAL DESCRIPTION FUNCTIONAL PIN DESCRIPTION H-BRIDGE OUTPUT 1, 2 (OUT1 AND OUT2) These pins are the outputs of the H-Bridge with integrated output FET body diodes. The bridge output is controlled using the IN1, IN2, D1, and D2 inputs. The outputs have active current limiting above 6.5 A. The outputs also have thermal shutdown (tri-state latch-OFF) with hysteresis as well as short circuit latch-OFF protection. A disable timer (time t b) incorporated to detect currents that are higher than active current limit is activated at each output activation to facilitate detecting hard output short conditions (see Figure 9, page 9). CHARGE PUMP CAPACITOR (CCP) Charge pump output pin. A filter capacitor (up to 33 nF) can be connected from the CCP pin and PGND. The device can operate without the external capacitor, although the CCP capacitor helps to reduce noise and allows the device to perform at maximum speed, timing, and PWM frequency. 33886 16 Analog Integrated Circuit Device Data Freescale Semiconductor FUNCTIONAL DEVICE OPERATION FUNCTIONAL PIN DESCRIPTION FUNCTIONAL DEVICE OPERATION SHORT CIRCUIT PROTECTION If an output short circuit condition is detected, the power outputs tri-state (latch-OFF) independent of the input (IN1 and IN2) states, and the fault status output flag is set logic Low. If the D1 input changes from logic High to logic Low, or if the D2 input changes from logic Low to logic High, the output bridge will become operational again and the fault status flag will be reset (cleared) to a logic High state. The output stage will always switch into the mode defined by the input pins (IN1, IN2, D1, and D2), provided the device junction temperature is within the specified operating temperature. ACTIVE CURRENT LIMITING The maximum current flow under normal operating conditions is internally limited to ILIM (5.2 A to 7.8 A). When the maximum current value is reached, the output stages are tri-stated for a fixed time (t a) of 20 s typical. Depending on the time constant associated with the load characteristics, the current decreases during the tri-state duration until the next output ON cycle occurs (see Figures 9 and 12, page 9 and page 10, respectively). The current limiting threshold value is dependent upon the device junction temperature. When -40C < TJ < 160C, ILIM is between 5.2 A and 7.8 A. When TJ exceeds 160C, the ILIM current decreases linearly down to 2.5 A typical at 175C. Above 175C the device overtemperature circuit detects TLIM and overtemperature shutdown occurs (see Figure 7, page 8). This feature allows the device to remain operational for a longer time but at a regressing output performance level at junction temperatures above 160C. OVERTEMPERATURE SHUTDOWN AND HYSTERESIS If an overtemperature condition occurs, the power outputs are tri-state (latched-OFF) independent of the input signals and the fault status flag is set logic Low. To reset from this condition, D1 must change from logic High to logic Low, or D2 must change from logic Low to logic High. When reset, the output stage switches ON again, provided that the junction temperature is now below the overtemperature threshold limit minus the hysteresis. Note Resetting from the fault condition will clear the fault status flag. MAIN DIFFERENCES COMPARED TO MC33186DH1 * COD pin has been removed. Pin 8 is now a Do Not Connect (DNC) pin. * Pin 20 is no longer connected in the 20 HSOP package. It is now a DNC pin. * RDS(ON) max at TJ = 150C is now 225 m per each output transistor. * Maximum temperature operation is now 160C, as minimum thermal shutdown temperature has increased. * Current regulation limiting foldback is implemented above 160C TJ. * Thermal resistance junction to case has been increased from ~2.0C/W to ~5.0C/W. 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 17 FUNCTIONAL DEVICE OPERATION PERFORMANCE PERFORMANCE The 33886 is designed for enhanced thermal performance. The significant feature of this device is the exposed copper pad on which the power die is soldered. This pad is soldered on a PCB to provide heat flow to ambient and also to provide thermal capacitance. The more copper area on the PCB, the better the power dissipation and transient behavior will be. Example Characterization on a double-sided PCB: bottom side area of copper is 7.8 cm2; top surface is 2.7 cm2 (see Figure 21); grid array of 24 vias 0.3 mm in diameter. Figure 22 shows the thermal response with the device soldered on to the test PCB described in Figure 21. 100 10 Rth (C/W) 1 0,1 0,001 0,01 0,1 1 10 t, Time (s) 100 1000 10000 Figure 22. 33886 Thermal Response Top Side Bottom Side Figure 21. PCB Test Layout 33886 18 Analog Integrated Circuit Device Data Freescale Semiconductor TYPICAL APPLICATIONS TYPICAL APPLICATIONS A typical application schematic is shown in Figure 23. For precision high-current applications in harsh, noisy environments, the V+ by-pass capacitor may need to be substantially larger. DC MOTOR V+ 33886 AGND V+ CCP OUT1 33 nF + 47 F OUT2 D2 D1 FS PGND IN1 IN2 IN2 IN1 FS D1 D2 Figure 23. 33886 Typical Application Schematic 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 19 PACKAGING PACKAGE DIMENSIONS PACKAGING PACKAGE DIMENSIONS Important For the most current revision of the package, visit www.freescale.com and perform a keyword search on 98ASH70702A listed below. DH SUFFIX VW (Pb-FREE) SUFFIX 20-PIN HSOP PLASTIC PACKAGE 98ASH70702A ISSUE A PIN ONE ID h X 45 _ E2 20 1 D2 e 18X E3 D1 e/2 D 10 11 EXPOSED HEATSINK AREA B E1 E bbb M E4 A 10X BOTTOM VIEW C B Y H DATUM PLANE EEE CCC CCC EEE b1 A A2 c C SEATING PLANE b aaa M C A SECTION W-W L1 W L A1 q W A3 GAUGE PLANE bbb C c1 NOTES: 1. CONTROLLING DIMENSION: MILLIMETER. 2. DIMENSIONS AND TOLERANCES PER ASME Y14.5M, 1994. 3. DATUM PLANE -H- IS LOCATED AT BOTTOM OF LEAD AND IS COINCIDENT WITH THE LEAD WHERE THE LEAD EXITS THE PLASTIC BODY AT THE BOTTOM OF THE PARTING LINE. 4. DIMENSIONS D AND E1 DO NOT INCLUDE MOLD PROTRUSION. ALLOWABLE PROTRUSION IS 0.150 PER SIDE. DIMENSIONS D AND E1 DO INCLUDE MOLD MISMATCH AND ARE DETERMINED AT DATUM PLANE -H-. 5. DIMENSION b DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR PROTRUSION SHALL BE 0.127 TOTAL IN EXCESS OF THE b DIMENSION AT MAXIMUM MATERIAL CONDITION. 6. DATUMS -A- AND -B- TO BE DETERMINED AT DATUM PLANE -H-. 7. DIMENSION D DOES NOT INCLUDE TIEBAR PROTRUSIONS. ALLOWABLE TIEBAR PROTRUSIONS ARE 0.150 PER SIDE. MILLIMETERS MIN MAX 3.000 3.400 0.100 0.300 2.900 3.100 0.00 0.100 15.800 16.000 11.700 12.600 0.900 1.100 13.950 14.450 10.900 11.100 2.500 2.700 6.400 7.200 2.700 2.900 0.840 1.100 0.350 BSC 0.400 0.520 0.400 0.482 0.230 0.320 0.230 0.280 1.270 BSC --- 1.100 q 0_ 8_ aaa 0.200 bbb 0.100 DIM A A1 A2 A3 D D1 D2 E E1 E2 E3 E4 L L1 b b1 c c1 e h (1.600) DETAIL Y 33886 20 Analog Integrated Circuit Device Data Freescale Semiconductor 5.0 A H-BRIDGE THERMAL ADDENDUM - REVISION 2.0 5.0 A H-BRIDGE 33886 THERMAL ADDENDUM - REVISION 2.0 Introduction This thermal addendum is provided as a supplement to the MC33186 technical data sheet. The addendum provides thermal performance information that may be critical in the design and development of system applications. All electrical, application, and packaging information is provided in the data sheet. 20-PIN HSOP-EP Packaging and Thermal Considerations The MC33186 is offered in a 20 pin HSOP exposed pad, single die package. There is a single heat source (P), a single junction temperature (TJ), and thermal resistance (RJA). TJ = RJA . DH SUFFIX VW (Pb-FREE) SUFFIX 98ASH70702A 20-PIN HSOP-EP P The stated values are solely for a thermal performance comparison of one package to another in a standardized environment. This methodology is not meant to and will not predict the performance of a package in an applicationspecific environment. Stated values were obtained by measurement and simulation according to the standards listed below. Note For package dimensions, refer to the 33886 device data sheet. Standards Table 6. Thermal Performance Comparison Thermal Resistance [C/W] RJA(1)(2) 20 RJB(2)(3) 6.0 RJA(1)(4) 52 RJC (5) 1.0 1.0 0.2 1.0 0.2 * All measurements are in millimeters NOTES: Soldermast openings 1.Per JEDEC JESD51-2 at natural convection, still air condition. 2.2s2p thermal test board per JEDEC JESD51-5 and JESD51-7. 3.Per JEDEC JESD51-8, with the board temperature on the center trace near the center lead. 4.Single layer thermal test board per JEDEC JESD51-3 and JESD51-5. 5.Thermal resistance between the die junction and the exposed pad surface; cold plate attached to the package bottom side, remaining surfaces insulated. 20 Terminal HSOP-EP 1.27 mm Pitch 16.0 mm x 11.0 mm Body 12.2 mm x 6.9 mm Exposed Pad Thermal vias connected to top buried plane Figure 24. Thermal Land Pattern for Direct Thermal Attachment According to JESD51-5 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 21 5.0 A H-BRIDGE THERMAL ADDENDUM - REVISION 2.0 A AGND FS IN1 V+ V+ OUT1 OUT1 DNC PGND PGND 1 2 3 4 5 6 7 8 9 10 20 19 18 17 16 15 14 13 12 11 DNC IN2 D1 CCP V+ OUT2 OUT2 D2 PGND PGND 33886 Pin Connections 20-Pin HSOP 1.27 mm Pitch 16.0 mm x 11.0 mm Body 12.2 mm x 6.9 mm Exposed Pad Figure 25. Thermal Test Board Device on Thermal Test Board Material: Outline: Single layer printed circuit board FR4, 1.6 mm thickness Cu traces, 0.07 mm thickness 80 mm x 100 mm board area, including edge connector for thermal testing Area A: Cu heat-spreading areas on board surface Ambient Conditions: Natural convection, still air Table 7. Thermal Resistance Performance Thermal Resistance Area A (mm2) C/W RJA 0.0 52 300 36 600 32 0.0 10 300 7.0 600 6.0 RJS RJA is the thermal resistance between die junction and ambient air. RJS is the thermal resistance between die junction and the reference location on the board surface near a center lead of the package (see Figure 25). 33886 22 Analog Integrated Circuit Device Data Freescale Semiconductor Thermal Resistance [C/W] 5.0 A H-BRIDGE THERMAL ADDENDUM - REVISION 2.0 60 50 40 30 x RJA 20 10 0 0 300 Heat spreading area A [mm] 600 Figure 26. Device on Thermal Test Board RJA Thermal Resistance [C/W] 100 x RJA 10 1 0.1 1.00E-03 1.00E-02 1.00E-01 1.00E+00 1.00E+01 1.00E+02 1.00E+03 1.00E+04 time[s] Time(s) Figure 27. Transient Thermal Resistance RJA Device on Thermal Test Board Area A = 600 (mm2) 33886 Analog Integrated Circuit Device Data Freescale Semiconductor 23 REVISION HISTORY REVISION HISTORY REVISION DATE DESCRIPTION OF CHANGES 7.0 7/2005 * * * Implemented Revision History page Added Thermal Addendum Converted to Freescale format 8.0 2/2007 * * Updated data sheet format Removed Peak Package Reflow Temperature During Reflow (solder reflow) parameter from Maximum Ratings on page 4. Added note with instructions to obtain this information from www.freescale.com. 33886 24 Analog Integrated Circuit Device Data Freescale Semiconductor How to Reach Us: Home Page: www.freescale.com Web Support: http://www.freescale.com/support USA/Europe or Locations Not Listed: Freescale Semiconductor, Inc. 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Box 5405 Denver, Colorado 80217 1-800-441-2447 or 303-675-2140 Fax: 303-675-2150 LDCForFreescaleSemiconductor@hibbertgroup.com MC33886 Rev 8.0 2/2007 RoHS-compliant and/or Pb-free versions of Freescale products have the functionality and electrical characteristics of their non-RoHS-compliant and/or non-Pb-free counterparts. For further information, see http://www.freescale.com or contact your Freescale sales representative. For information on Freescale's Environmental Products program, go to http:// www.freescale.com/epp. Information in this document is provided solely to enable system and software implementers to use Freescale Semiconductor products. There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits or integrated circuits based on the information in this document. Freescale Semiconductor reserves the right to make changes without further notice to any products herein. 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