DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 SENSOR SIGNAL CONDITIONING IC FOR CLOSED-LOOP MAGNETIC CURRENT SENSOR FEATURES 1 • Designed For Sensors From VACUUMSCHMELZE (VAC) • Single Supply: 5 V • Power Output: H-Bridge • Designed For Driving Inductive Loads • Excellent DC Precision • Wide System Bandwidth • High-Resolution, Low-Temperature Drift • Built-In Degauss System • Extensive Fault Detection • External High-Power Driver Option 23 SUPPORTS DEFENSE, AEROSPACE, AND MEDICAL APPLICATIONS • • • • • • • Controlled Baseline One Assembly/Test Site One Fabrication Site Available in Military (–55°C/125°C) Temperature Range (1) Extended Product Life Cycle Extended Product-Change Notification Product Traceability APPLICATIONS • • • • • Generator/Alternator Monitoring and Control Frequency and Voltage Inverters Motor Drive Controllers System Power Consumption Photovoltaic Systems (1) Custom temperature ranges available DESCRIPTION/ORDERING INFORMATION The DRV401 is designed to control and process signals from specific magnetic current sensors made by VACUUMSCHMELZE GmbH & Co. KG (VAC). A variety of current ranges and mechanical configurations are available. Combined with a VAC sensor, the DRV401 monitors both ac and dc currents to high accuracy. Provided functions include: probe excitation, signal conditioning of the probe signal, signal loop amplifier, an H-bridge driver for the compensation coil, and an analog signal output stage that provides an output voltage proportional to the primary current. It offers overload and fault detection, as well as transient noise suppression. The DRV401 can directly drive the compensation coil or connect to external power drivers. Therefore, the DRV401 combines with sensors to measure small to very large currents. To maintain the highest accuracy, the DRV401 can demagnetize (degauss) the sensor at power-up and on demand. 1 2 3 Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. PowerPAD is a trademark of Texas Instruments. All other trademarks are the property of their respective owners. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2008, Texas Instruments Incorporated DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. ORDERING INFORMATION (1) (1) (2) PRODUCT PACKAGE-LEAD PACKAGE DESIGNATOR (2) PACKAGE MARKING DRV401 SO-20 DWP DRV401M For the most current package and ordering information see the Package Option Addendum at the end of this document, or see the TI web site at www.ti.com. Package drawings, standard packing quantities, thermal data, symbolization, and PCB design guidelines are available at www.ti.com/sc/package. Patents Pending. Compensation PWM PWM Compensation Winding Primary Winding RS ICOMP1 ICOMP2 DRV401 Diff Amp Magnetic Core Field Probe IS2 IP VOUT REFIN IS1 Probe Interface Integrator Filter Timing, Error Detection, and Power Control H−Bridge Driver Degauss VREF VREF +5V GND ABSOLUTE MAXIMUM RATINGS (1) over operating free-air temperature range (unless otherwise noted) MIN Supply voltage Voltage (2) Differential amplifier (3) Signal Input terminals: V –0.5 VDD + 0.5 V –10 +10 V ±75 mA Current at IS1 and IS2 Storage temperature ESD rating (1) (2) (3) (4) 2 ±25 mA +250 mA –55 +150 °C –55 (4) Operating junction temperature Human body model (HBM) UNIT +7 Current (pins other than IS1 and IS2) (2) ICOMP short circuit MAX +150 °C Pins IAIN1 and IAIN2 only 1 kV All other pins 4 kV Stresses above these ratings may cause permanent damage. Exposure to absolute maximum conditions for extended periods may degrade device reliability. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those specified is not supported. Input terminals are diode-clamped to the power-supply rails. Input signals that can swing more than 0.5 V beyond the supply rails must be current limited, except for the differential amplifier input pins. These inputs are not internally protected against over voltage. The differential amplifier input pins must be limited to 5 mA, max or ±10 V, max. Power-limited; observe maximum junction temperature. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 ELECTRICAL CHARACTERISTICS (1) Boldface limits apply over the specified temperature range: TJ = –55°C to +125°C. At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, and zero output current ICOMP, unless otherwise noted. PARAMETER CONDITIONS DRV401 MIN TYP MAX ±0.01 ±0.1 UNITS RL = 10 kΩ to 2.5 V, VREFIN = 2.5 V DIFFERENTIAL AMPLIFIER OFFSET VOLTAGE VOS Offset voltage, RTO (2) (3) dVOS/dT Drift, RTO VOS Offset voltage, RTO (2) (3) Gain 4 V/V CMRR vs common-mode, RTO –1 V to +6 V, VREF = 2.5 V PSRR vs power-supply, RTO VREF not included Gain 4 V/V (3) mV µV/°C ±0.1 ±0.17 mV ±50 ±280 µV/V ±4 ±50 µV/V SIGNAL INPUT Common-mode voltage range –1 (VDD) + 1 V SIGNAL OUTPUT Signal over-range indication (OVER-RANGE), Delay (3) Voltage output swing from negative rail OVER-RANGE trip level VIN = 1 V step (3) (3) Voltage putput swing from positive rail (3), OVER-RANGE trip level ISC Short-circuit current (3) , (4) I = +2.5 mA, CMP trip level I = –2.5 mA, CMP trip level VDD – 85 +85 mV mV VOUT connected to GND –18 mA VOUT connected to VDD +20 mA 4 Gain error ±0.02 Gain error drift (1) (2) (3) (4) +48 VDD – 48 Gain, VOUT/VIN_DIFF Linearity error µs 2.5 to 3.5 V/V =0.3 ±0.1 RL = 1 kΩ 10 % ppm/°C ppm For Electromigration derating curves, please refer to http://focus.ti.com/pdfs/hirel/mltry/EP_Reliability_Information.pdf. Parameter value referred to output (RTO). See Typical Characteristics curves. Total input resistance and comparator threshold current are inversely related. See Figure 2a. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 3 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com ELECTRICAL CHARACTERISTICS (continued) Boldface limits apply over the specified temperature range: TJ = –55°C to +125°C. At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, and zero output current ICOMP, unless otherwise noted. PARAMETER CONDITIONS DRV401 MIN TYP MAX UNITS FREQUENCY RESPONSE BW–3dB SR Bandwidth (5) Slew rate (5) Settling time, large-signal (5) Settling time (5) 2 MHz CMVR = –1 V to = +4 V 6.5 V/µs dV ± 2 V to 1%, No external filter 0.9 µs dV ± 0.4 V to 0.01% 14 µs INPUT RESISTANCE Differential 16.5 20 23.5 kΩ Common-mode 41 50 59 kΩ External reference input 41 50 59 kΩ NOISE Output voltage noise density, f = 1 kHz, RTO (5) en Compensation loop disabled 170 nV/√Hz COMPENSATION LOOP PSRR DC STABILITY Probe f = 250 kHz, RLOAD = 20 Ω Offset error (6) Deviation from 50% PWM, Pin gain = L 0.03 % Offset error drift (5) Deviation from 50% PWM, Pin gain = L 7.5 ppm/°C Gain, pin gain = L (5) |VICOMP1| – |VICOMP2| Power-supply rejection ratio Probe loop f = 250 kHz –200 25 200 500 ppm/V ppm/V FREQUENCY RESPONSE Open-loop gain, two modes, 7.8 kHz Pin gain H/L 24/32 dB –0.7 –0.7 to VDD V 47 59 71 Ω 60 75 90 Ω 300 1500 PROBE COIL LOOP Input voltage clamp range Internal resistor, IS1 or IS2 to VDD1 Field probe current < 50 mA (5) RHIGH Internal resistor, IS1 or IS2 to GND1 (5) RLOW Resistance mismatch between IS1 and IS2 (5) ppm of RHIGH + RLOW Total input resistance (7) ppm 134 200 Ω Comparator threshold current (7) 22 28 34 mA Minimum probe loop half-cycle (5) 250 280 310 ns Probe loop minimum frequency 250 No oscillation detect (error) suppression kHz µs 35 COMPENSATION COIL DRIVER, H-BRIDGE Peak current (5) VICOMP1 – VICOMP2 = 4.0VPP Voltage swing 20 Ω load 250 Output common-mode voltage Wire break detect, threshold current mA 4.2 VPP VDD2/2 (8) ICOMP1 and ICOMP2 railed V 33 57 2.5 2.505 mA VOLTAGE REFERENCE (5) (6) (7) (8) 4 Voltage (5) No load Drift (5) No load 2.495 ±5 V ppm/°C See Typical Characteristics curves. For VAC sensors, 0.2% of PWM offset approximately corresponds to 10 mA primary current offset per winding. Total input resistance and comparator threshold current are inversely related. See Figure 2a. See Compensation Driver section in Applications Information. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 ELECTRICAL CHARACTERISTICS (continued) Boldface limits apply over the specified temperature range: TJ = –55°C to +125°C. At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, and zero output current ICOMP, unless otherwise noted. PARAMETER CONDITIONS Drift (5) No load DRV401 MIN 2.491 PSRR (5) ISC TYP ±15 MAX UNITS 2.509 V ±200 µV/V Load regulation (5) Load to GND/VDD, dl = 0 mA to 5 mA 0.15 mV/mA Short-circuit current REFOUT connected to VDD +20 mA REFOUT connected to GND –18 mA See Timing Diagram 106 DEMAGNETIZATION Duration 130 (7) ms DIGITAL I/O LOGIC INPUTS (DEMAG, GAIN, and CCdiag Pins) CMOS Type Levels Pull-up high current (CCdiag) 3.5 < VIN < VDD Pull-up low current (CCdiag) 0 < VIN < 1.5 Logic input leakage current 0 < VIN < VDD µA 160 µA 5 0.01 Logic level, input: L/H Hysteresis 5 µA 2.1/2.8 V 0.7 V 0.3 V OUTPUTS (ERROR AND OVER-RANGE Pins) Logic level, output: L 4 mA sink Logic level, output: H No Internal Pull-Up OUTPUTS (PWM and PWM Pins) Push-pull type Logic level L 4 mA sink Logic level H 4 mA source 0.2 V (VDD) – 0.4 V POWER SUPPLY VDD Specified voltage range VRST Power-on reset threshold IQ Quiescent current [I(VDD1) + I(VDD2)] 4.5 5 5.5 1.8 ICOMP = 0 mA, Sensor not connected V 6.8 Brownout voltage level (9) Brownout indication delay V mA 5 V 135 µs TEMPERATURE RANGE TJ Specified range TJ Operating range θJA Package thermal resistance SO PowerPAD surface-mount (10) –40 +125 °C –50 +150 °C 27 °C/W (9) See Typical Characteristics curves. (10) See Applications Information section for information on power dissipation, layout considerations, and proper PCB soldering and heat-sinking technique. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 5 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com PIN CONFIGURATIONS Top View DWP PWM 1 20 IS1 PWM 2 19 GND1 ERROR 3 18 IS2 DEMAG 4 17 VDD1 GAIN 5 16 OVER- RANGE REFOUT 6 15 CCdiag REFIN 7 14 VDD2 VOUT 8 13 ICOMP1 IAIN2 9 12 ICOMP2 IAIN1 10 11 GND2 Exposed Thermal Pad on Underside, Connect to GND1 Wide- Body SO- 20 PIN ASSIGNMENTS TERMINAL NAME NO. DESCRIPTION ERROR 1 Error flag: open-drain output, see the Error Conditions section. DMAG 2 Control input, see the Demagnetization section. GAIN 3 Control input for open-loop gain: low = normal, high = –8 dB. REFOUT 4 Output for internal 2.5 V reference voltage. REFIN 5 Input for zero reference to differential amplifier. VOUT 6 Output for differential amplifier. IAIN2 7 Noninverting input of differential amplifier. IAIN1 8 Inverting input of differential amplifier. GND2 9 Ground connection. Connect to GND1. ICOMP2 10 Output 2 of compensation coil driver. ICOMP1 11 Output 1 of compensation coil driver. VDD2 12 Supply voltage. Connect to VDD1. CCdiag 13 Control input for wire-break detection: high = enable. OVER-RANGE 14 Open-drain output for over-range indication: low = over-range. VDD1 15 Supply voltage. IS2 16 Probe connection 2. GND1 17 Ground connection. IS1 18 Probe connection 1. PWM 19 PWM output from probe circuit (inverted). PWM 20 PWM output from probe circuit. Exposed Thermal Pad – Connect to GND1. 6 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 TYPICAL CHARACTERISTICS At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, unless otherwise noted. DRV401 AND SENSOR: OUTPUT VOLTAGE NOISE DENSITY (Sensor M4645−X080, RSHUNT = 10Ω, Mode = Low) DRV401 AND SENSOR: OFFSET vs SUPPLY VOLTAGE 0.04 100 0.03 60Hz Line Frequency and Multiples (measured in a 60Hz environment) M4645−X211 M4645−X211 0.01 VN (µV/√Hz) IPRIM (A) 0.02 0 M4645−X080 −0.01 −0.02 Divided Field Probe Frequency 10 −0.03 −0.04 4.1 4.3 4.5 4.7 4.9 5.1 5.3 5.5 5.7 5.9 6.1 0.1 0.1 VDD (V) 1 10 100 1k 10k 100k Frequency (Hz) DRV401 AND SENSOR: ABSOLUTE ERROR (Soldered DWP−20 with 1 Square−Inch Copper Pad) (Measurements by Vacuumschmelza GmbH) 0.3 1.20 T = −50_ C T = +25_C T = +85_C T = +125_ C DRV401 with M4645−X600 Sensor DRV401 with M4645−X211 Sensor DRV401 with M4645−X080 Sensor 1.15 1.10 Normalized Gain 0.2 Absolute Error (A) GAIN FLATNESS vs FREQUENCY (Measurements by Vacuumschmelze GmbH) 0.1 0 −0.1 1.05 1.00 0.95 0.90 0.85 −0.2 TC (RSHUNT) ±25ppm/_ C. −0.3 −300 −200 0.80 10 −100 0 100 200 100 300 1k 10k 100k 1M Frequency (Hz) Primary Current (A) DIFFERENTIAL AMPLIFIER: VOLTAGE OFFSET PRODUCTION DISTRIBUTION 3A ICOMP OVERLOAD RECOVERY (Measurements by Vacuumschmelze GmbH) RTO Over−Range 2000A/div 2V/div VOUT VOUT ERROR Population Over−Range ERROR 0 20 40 60 80 100 120 140 160 180 200 Time (µs) IPRIM −50 −45 −40 −35 −30 −25 −20 −15 −10 −5 0 5 10 15 20 25 30 35 40 45 50 IPRIM NOTE: IPRIM = 3000A corresponds to ICOMP = 3A. Voltage Offset (µV) Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 7 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com TYPICAL CHARACTERISTICS (continued) At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, unless otherwise noted. DIFFERENTIAL AMPLIFIER: GAIN vs FREQUENCY DIFFERENTIAL AMPLIFIER: OFFSET VOLTAGE vs TEMPERATURE, RTO 20 20 16 15 10 8 Gain (dB) Input VOS (µV) 12 4 Sample Average 0 −4 −8 5 0 −5 −10 −12 −15 −16 −20 −50 −20 −25 25 0 75 50 100 125 10 150 100 1k 10k DIFFERENTIAL AMPLIFIER: PSRR AND CMRR vs FREQUENCY DIFFERENTIAL AMPLIFIER: OUTPUT VOLTAGE vs OUTPUT CURRENT 5.0 −40_ C PSRR +25_C Output Voltage (V) CMRR 80 60 40 +125_ C 4.8 +85_C 4.7 0.3 +85_ C +125_C 0.2 20 0.1 0 0 −40_ C +25_ C 10 100 1k 10k 100k 1M 2M 0 1 2 3 4 5 6 25 1000 Short−Circuit Current (mA) Noise Density (nV/√Hz) 100 Autozero Frequency = 69kHz Sensor Not Running en = 162nV/√Hz (average over 250Hz to 50kHz) 10k 9 10 VOUT Shorted to 5V 20 1k 8 DIFFERENTIAL AMPLIFIER: SHORT−CIRCUIT CURRENT vs TEMPERATURE DIFFERENTIAL AMPLIFIER: OUTPUT NOISE DENSITY 100 7 Load Current (mA) Frequency (Hz) 100k 15 10 5 0 −5 −10 −15 −20 1M −25 −50 VOUT Shorted to 0V −25 Frequency (Hz) 8 10M 4.9 100 10 1M Frequency (Hz) 120 PSRR and CMRR (dB) 100k Temperature (_C) 0 25 50 75 100 125 150 Temperature (_ C) Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 TYPICAL CHARACTERISTICS (continued) At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, unless otherwise noted. DIFFERENTIAL AMPLIFIER: TA = +25_C LARGE−SIGNAL STEP RESPONSE 3.8 3.8 3.6 3.4 3.6 3.2 3.4 3.2 3.0 3.0 Voltage (V) Voltage (V) DIFFERENTIAL AMPLIFIER: TA = −50_C LARGE−SIGNAL STEP RESPONSE 2.8 2.6 2.4 2.8 2.6 2.4 2.2 2.2 2.0 2.0 1.8 1.6 1.8 1.6 1.4 1.4 1µs/div 1µs/div DIFFERENTIAL AMPLIFIER: OVER−RANGE DELAY vs TEMPERATURE 3.8 3.5 3.6 3.4 3.4 3.2 3.3 Over−Range Delay (µs) Voltage (V) DIFFERENTIAL AMPLIFIER: TA = +150_C LARGE−SIGNAL STEP RESPONSE 3.0 2.8 2.6 2.4 2.2 2.0 1.8 1.6 At 5.0V VIN Step 0V to ±1V 3.2 Negative Over−Range 3.1 3.0 2.9 Positive Over−Range 2.8 2.7 2.6 2.5 1.4 1µs/div −50 −25 0 25 50 75 100 125 150 Temperature (_ C) DIFFERENTIAL AMPLIFIER: NEGATIVE SLEW RATE vs TEMPERATURE DIFFERENTIAL AMPLIFIER: POSITIVE SLEW RATE vs TEMPERATURE −6.5 At 5.0V 7.4 −6.6 7.3 −6.7 7.2 −6.8 Slew Rate (V/µs) Slew Rate (V/µs) 7.5 7.1 7.0 6.9 6.8 −6.9 −7.0 −7.1 −7.2 6.7 −7.3 6.6 −7.4 6.5 −50 −25 0 25 50 75 100 125 150 At 5.0V −7.5 −50 −25 0 25 50 75 100 125 150 Temperature (_ C) Temperature (_ C) Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 9 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com TYPICAL CHARACTERISTICS (continued) At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, unless otherwise noted. Gain VPWMAVERAGE /(VICOMP1, VICOMP2) (dB) DIFFERENTIAL AMPLIFIER: REFIN RESISTANCE vs TEMPERATURE 50.250 RREF IN (kΩ ) 50.125 50.000 49.875 49.750 49.625 −50 −25 0 25 50 75 100 125 COMPENSATION LOOP: SMALL−SIGNAL GAIN 70 60 50 Pin Gain = Low 40 Pin Gain = High 30 20 10 0 100 150 1k 100k COMPENSATION LOOP: DC GAIN: DUTY CYCLE ERROR CHANGE COMPENSATION LOOP: DUTY CYCLE ERROR vs TEMPERATURE 2000 VICOMP1 − VICOMP2 = 4.2V ILOAD = 210mA 1500 Gain Pin Low 1000 500 Population Duty Cycle Error (ppm) 10k Frequency (Hz) Temperature (_ C) 0 At 250kHz, 5.0V −500 −1000 At 400kHz, 5.0V −2000 −50 −25 0 25 50 75 100 125 −200 −180 −160 −140 −120 −100 −80 −60 −40 −20 0 20 40 60 80 100 120 140 160 180 200 −1500 150 Temperature (_ C) Gain (ppm/V) ICOMP OUTPUT SWING TO RAIL vs OUTPUT CURRENT 5.00 4.75 +125_C Output Swing (V) 4.50 −50_ C +25_ C 4.25 4.00 1.00 0.75 0.50 +125_C +25_ C −50_ C 0.25 0 0 50 100 150 200 250 300 Probe Comparator Threshold Current (mA) PROBE COMPARATOR THRESHOLD CURRENT vs TEMPERATURE 35.0 32.5 30.0 27.5 25.0 −50 −25 10 0 25 50 75 100 125 150 Temperature (_ C) Output Current (mA) Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 TYPICAL CHARACTERISTICS (continued) At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, unless otherwise noted. OUTPUT IMPEDANCE MISMATCH OF IS1 AND IS2 vs TEMPERATURE PROBE DRIVER: INTERNAL RESISTOR vs TEMPERATURE 90 Output Impedance Mismatch (Ω) 0.10 85 80 Resistance (Ω) Driver L 75 70 65 60 Driver H 55 50 45 −50 −25 0.08 0.06 0.04 0.02 0 0 25 50 75 100 125 150 −50 −25 0 Temperature (_ C) 25 50 75 100 125 150 Temperature (_ C) VOLTAGE REFERENCE PRODUCTION DISTRIBUTION VOLTAGE REFERENCE vs LOAD CURRENT 2.5010 2.5008 2.5006 Population VREF (V) 2.5004 2.5002 2.5000 2.4998 2.4996 2.4994 2.4990 −6 −4 −2 0 2 4 2.4950 2.4955 2.4960 2.4965 2.4970 2.4975 2.4980 2.4985 2.4990 2.4995 2.5000 2.5005 2.5010 2.5015 2.5020 2.5025 2.5030 2.5035 2.5040 2.5045 2.5050 2.4992 6 ILOAD (mA) VREF (V) VOLTAGE REFERENCE vs TEMPERATURE VOLTAGE REFERENCE DRIFT PRODUCTION DISTRIBUTION 2.525 2.520 2.515 Population VREF (V) 2.510 2.505 2.500 2.495 2.490 2.485 2.480 −50 0 2.5 5.0 7.5 10.0 12.5 15.0 17.5 20.0 22.5 25.0 27.5 30.0 32.5 35.0 37.5 40.0 42.5 45.0 47.5 50.0 2.475 −25 0 25 50 75 100 125 150 Temperature (_ C) Voltage Reference Drift (ppm/_ C) Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 11 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com TYPICAL CHARACTERISTICS (continued) At TA = +25°C and VDD1 = VDD2 = +5 V with external 100 kHz filter BW, unless otherwise noted. OSCILLATOR PRODUCTION DISTRIBUTION 250 253 256 259 262 265 268 271 274 277 280 283 286 289 292 295 298 301 304 307 310 200 150 175 100 125 50 75 0 25 −25 −75 −50 −125 −100 −175 −150 −200 Population Population VOLTAGE REFERENCE POWER−SUPPLY REJECTION PRODUCTION DISTRIBUTION Minimum Probe Loop Half−Cycle (ns) PSR (µV/V) OSCILLATOR vs SUPPLY VOLTAGE OSCILLATOR vs TEMPERATURE 310 Minimum Probe Loop Half−Cycle (ns) Minimum Probe Loop Half−Cycle (ns) 310 305 300 295 290 285 280 275 270 265 260 255 250 −50 −25 0 25 50 75 100 125 305 300 295 290 285 280 275 270 265 260 255 250 4.3 150 4.6 4.9 Temperature (_C) 5.2 5.5 5.8 6.0 VDD (V) BROWN−OUT VOLTAGE vs TEMPERATURE 4.20 Brown−Out Voltage (V) 4.15 4.10 4.05 4.00 3.95 3.90 3.85 3.80 −50 −25 0 25 50 75 100 125 150 Temperature (_ C) 12 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 APPLICATION INFORMATION FUNCTIONAL PRINCIPLE OF CLOSED-LOOP CURRENT SENSORS WITH MAGNETIC PROBE USING THE DRV401 Closed-loop current sensors measure current over wide frequency ranges, including dc. These types of devices offer a contact-free method as well as excellent galvanic isolation performance combined with high resolution, accuracy, and reliability. At dc and in low-frequency ranges, the magnetic field induced from the current in the primary winding is compensated by a current flowing through a compensation winding. A magnetic field probe, located in the magnetic core loop, detects the magnetic flux. This probe delivers the signal to the amplifier that drives the current through the compensation coil, bringing the magnetic flux back to zero. This compensation current is proportional to the primary current, relative to the winding ratio. In higher frequency ranges, the compensation winding acts as the secondary winding in the current transformer, while the H-bridge compensation driver is rolled off and provides low output impedance. A difference amplifier senses the voltage across a small shunt resistor that is connected to the compensation loop. This difference amplifier generates the output voltage that is referenced to REFIN and is proportional to the primary current. Figure 1 shows the DRV401 used as a compensation current sensor. Compensation RS ICOMP1 Compensation Winding Primary Winding ICOMP2 DRV401 Diff Amp Magnetic Core Field Probe IS2 IP VOUT REFIN IS1 Probe Interface Integrator Filter Timing, Error Detection, and Power Control H−Bridge Driver Degauss VREF VREF +5V GND Figure 1. Principle of Compensation Current Sensor With the DRV401 FUNCTIONAL DESCRIPTION The DRV401 operates from a single +5 V supply. It is a complete sensor signal conditioning circuit that directly connects to the current sensor, providing all necessary functions for the sensor operation. The DRV401 provides magnetic field probe excitation, signal conditioning, and compensation coil driver amplification. In addition, it detects error conditions and handles overload situations. A precise differential amplifier allows translation of the compensation current into an output voltage using a small shunt resistor. A buffered voltage reference can be used for comparator, analog-to-digital converter (ADC), or bipolar zero reference voltages. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 13 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com Dynamic error correction ensures high dc precision over temperature and long-term accuracy. The DRV401 uses analog signal conditioning; the internal loop filter and integrator are switched capacitor-based circuits. Therefore, the DRV401 allows combination with high-precision sensors for exceptional accuracy and resolution. The typical characteristic curve, DRV401 and Sensor Linearity, shows an example of the linearity and temperature stability achieved by the device. A demagnetization cycle can be initiated on demand or on power-up. This cycle reduces offset and restores high performance after a strong overload condition. An internal clock and counter logic generate the degauss function. The same clock controls power-up, overload detection and recovery, error, and time-out conditions. The DRV401 is built on a highly reliable CMOS process. Unique protection cells at critical connections enable the design to handle inductive energy. MAGNETIC PROBE (SENSOR) INTERFACE The magnetic field probe consists of an inductor wound on a soft magnetic core. The probe is connected between pins IS1 and IS2 of the probe driver that applies approximately +5 V (the supply voltage) through resistors across the probe coil (see Figure 2a). The probe core reaches saturation at a current of typically 28 mA (see Figure 2a). The comparator is connected to VREF by approximately 0.5 V. A current comparator detects the saturation and inverts the excitation voltage polarity, causing the probe circuit to oscillate in a frequency range of 250 kHz to 550 kHz. The oscillating frequency is a function of the magnetic properties of the probe core and its coil. The current rise rate is a function of the coil inductance: dI = L × V × dT. However, the inductance of the field probe is low while its core material is in saturation (the horizontal part of the hysteresis curve) and is high at the vertical part of the hysteresis curve. The resulting inductance and the series resistance determine the output voltage and current versus time performance characteristic. Without external magnetic influence, the duty cycle is exactly 50% because of the inherent symmetry of the magnetic hysteresis; the probe inductor is driven from –B saturation through the high inductance range to +B saturation and back again in a time-symmetric manner (see Figure 2b). If the core material is magnetized in one direction, a long and a short charge time result because the probe current through the inductors generates a field that either subtracts or adds to the flux in the probe core, either driving the probe core out of saturation or further into saturation (see Figure 2c). The current into the probe is limited by the voltage drops across the probe driver resistors. The DRV401 continuously monitors the logic magnetic flux polarity state. In the case of distortion noise and excessive overload that could fully saturate the probe, the overload control circuit recovers the probe loop. During an overload condition, the probe oscillation frequency increases to approximately 1.6 MHz until limited by the internal timing control. In an overload condition, the compensation current (ICOMP) driver cannot deliver enough current into the sensor secondary winding, and the magnetic flux in the sensor main core becomes uncompensated. 14 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 VDD1 Probe 55Ω 55Ω IS2 IS1 CMP 18Ω PWM VREF = 0.5V NOTE: MOS components function as switches only. a) Simplified probe interface circuit. The probe is connected between S1 and S2. B B H 2V/div V (IS1) 2V/div V (IS1) 500mV/div V (PWM)/10 500mV/div H V (PWM)/10 500ns/div 500ns/div b) Without an external magnetic field, the hysteresis curve is symmetrical and the probe loop generates 50% duty cycle. c) An external magnetic flux (H) generated from the primary current (IPRIM) shifts the hysteresis curve of the magnetic field probe in the H-axis and the probe loop generates a nonsymmetrical duty cycle. Figure 2. Magnetic Probe, Hysteresis, and Duty Cycle Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 15 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com The transition from normal operation to overload happens relatively slowly, because the inherent sensor transformer characteristics induce the initial primary current step, as shown in Figure 3. As the transformer-induced secondary current starts to decay, the compensation feedback driver increases its output voltage to maintain the sensor core flux compensation at zero. When the system compensation loop reaches its driving limit, the rising magnetic flux causes one of the probe PWM half-periods to become shorter. The minimum half-period of the probe oscillation is limited by the internal timing to 280 ns, based on the properties of the VAC magnetic sensors. After three consecutive cycles of the same half-period being shorter than 280 ns, the DRV401 goes into overload-latch mode. The device stores the ICOMP driver output signal polarity and continues producing the skewed-duty cycle PWM signal. This action prevents the loss of compensation signal polarity information during very strong overloads. In this case, both PWM half-periods are short and approximately equal, because the field probe stays completely in one of the saturated regions. The overload-latch condition is removed after the primary current goes low enough for the ICOMP driver to compensate, and both half-periods of the probe driver oscillation become longer than 280ns (the field probe comes out of the saturated region). Peak voltages and currents can be generated during normal operations as well as overload conditions. Therefore, both probe connection pins are internally protected against coupled energy from the magnetic core. Wiring between probe and IC inputs should be short and guarded against interference; see Layout Considerations.For reliable operation, error detection circuits monitor the probe operation: 1. If the probe driver comparator (CMP) output stays low longer than 32 µs, the ERROR flag asserts active, and the compensation current (ICOMP) is set to zero. 2. If the probe driver period is less than 275 ns on three consecutive pulses, the ERROR flag asserts active. See the Error Conditions section for more details. PWM PROCESSING The outputs PWM and PWM represent the probe output signal as a differential PWM signal. It can drive external circuitry or be used for synchronous ripple reduction. The PWM signal from the probe excitation and sense stage is internally connected to a high-performance, switched-capacitor integrator followed by an integrating-differentiating filter. This filter converts the PWM signal into a filtered delta signal and prepares it for driving the analog compensation coil driver. The gain roll-off frequency of the filter stage is set to provide high dc gain and loop stability. If additional gain is added from external circuitry, the internal gain can be reduced by 8 dB, asserting the GAIN pin high (see the External Compensation Coil Driver section). V(1Ω× IPRIM/10) 1 I COMP1 3 4 Sensor: 4 x 100 RSH = 10Ω Step Response 2kHz In V(Gain) = Low ICOMP2 Channel 1: 2V/div Channels 2−4: 500mV/div 2 VOUT 50µs/div A current pulse of 0A to 18A (Ch 1) generates the two ICOMP signals (Ch 3 and Ch 4). Ch 2 shows the resulting output signal, VOUT. This test uses the M4645-X030 sensor, no bandwidth limitation, but a 20-sample average. Figure 3. Primary Current Step Response 16 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 COMPENSATION DRIVER The compensation coil driver provides the driving current for the compensation coil. A fully differential driver stage offers high signal voltages to overcome the wire resistance of the coil with only +5 V supply. The compensation coil is connected between ICOMP1 and ICOMP2, both generating an analog voltage across the coil (see Figure 3) that turns into current from the wire resistance (and eventually from the inductance). The compensation current represents the primary current transformed by the turns ratio. A shunt resistor is connected in this loop and the high-precision difference amplifier translates the voltage from this shunt to an output voltage. Both compensation driver outputs provide low impedance over a wide frequency range to ensure smooth transitions between the closed-loop compensation frequency range and the high-frequency range, where the primary winding directly couples the primary current into the compensation coil at a rate set by the winding ratio. The two compensation driver outputs are designed with protection circuitry to handle inductive energy. However, additional external protection diodes might be necessary for high current sensors. For reliable operation, a wire break in the compensation circuit can be detected. If the feedback loop is broken, the integrating filter drives the outputs ICOMP1 and ICOMP2 to the opposite rails. With one of these pins coming within 300 mV to ground, a comparator tests for a minimum current flowing between ICOMP1 and ICOMP2. If this current stays below the threshold current level for at least 100 µs, the ERROR pin is asserted active (low). The threshold current level for this test is less than 57 mA at 25°C and 65 mA at –40°C, if the ICOMP pins are fully railed (see the Typical Characteristics). For sensors with high winding resistance (compensation coil resistance + RSHUNT) or connected to an external compensation driver, this function should be disabled by pulling the CCdiag pin low. V R MAX + OUT 65mA Where: VOUT equals the peak voltage between ICOMP1 and ICOMP2 at a 65mA drive current. RMAX equals the sum of the coil and the shunt resistance. EXTERNAL COMPENSATION COIL DRIVER An external driver for the compensation coil can be connected to the ICOMP1 and ICOMP2 outputs. To prevent a wire break indication, CCdiag has to be asserted low. An external driver can provide both a higher drive voltage and more drive current. It also moves the power dissipation to the external transistors, thereby allowing a higher winding resistance in the compensation coil and more current. Figure 4 shows a block diagram of an external compensation coil driver. To drive the buffer, either one or both ICOMP outputs can be used. Note, however, that the additional voltage gain could cause instability of the loop. Therefore, the internal gain can be reduced by approximately 8 dB by asserting the GAIN pin high. RSHUNT is connected to GND to allow for a single-ended external compensation driver. The differential amplifier can continue to sense the voltage, and used for the gain and over-range comparator or ERROR flag. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 17 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com V+ DRV401 ICOMP1 External Buffer Compensation Coil ICOMP2 V− RSHUNT Figure 4. DRV401 With External Compensation Coil Driver and RSHUNT Connected to GND SHUNT SENSE AMPLIFIER The differential (H-bridge) driver arrangement for the compensation coil requires a differential sense amplifier for the shunt voltage. This differential amplifier offers wide bandwidth and a high slew rate for fast current sensors. Excellent dc stability and accuracy result from an auto-zero technique. The voltage gain is 4 V/V, set by precisely matched and stable internal SiCr resistors. Both inputs of the differential amplifier are normally connected to the current shunt resistor. This resistor adds to the internal (10 kΩ) resistor, slightly reducing the gain in this leg. For best common-mode rejection (CMR), a dummy shunt resistor (R5) is placed in series with the REFIN pin to restore matching of both resistor dividers, as shown in Figure 5a. For gains of 4 V/V: R R4 ) R5 4+ 2+ R1 RSHUNT ) R3 With R2/R1 = R4/R3 = 4; R5 = RSHUNT × 4 Typically, the gain error resulting from the resistance of RSHUNT is negligible; for 70 dB of common-mode rejection, however, the match of both divider ratios needs to be better than 1/3000. The amplifier output can drive close to the supply rails, and is designed to drive the input of a SAR-type ADC; adding an RC low-pass filter stage between the DRV401 and the ADC is recommended. This filter not only limits the signal bandwidth but also decouples the high-frequency component of the converter input sampling noise from the amplifier output. For RF and CF values, refer to the specific converter recommendations in the specific product data sheet. Empirical evaluation may be necessary to obtain optimum results. The output can drive 100 pF directly and shows 50% overshoot with approximately 1 nF capacitance. Adding RF allows much larger capacitive loads, as shown in Figure 5b and Figure 5c. Note that with RF of only 20 Ω, the load capacitor should be either smaller than 1 nF or larger than 33 nF to avoid overshoot; with RF of 50 Ω this transient area is avoided. The reference input (REFIN) is the reference node for the exact output signal (VOUT). Connecting REFIN to the reference output (REFOUT) results in a live zero reference voltage of 2.5 V. Using the same reference for REFIN and the ADC avoids mismatch errors that exist between two reference sources. 18 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 ICOMP2 DRV401 Differential Amplifier Section R1 10kΩ R2 40kΩ Decoupling, Low−Pass Filter RF 50Ω VOUT R SHUNT ADC Differential Amplifier R3 10kΩ K2 R4 40kΩ REFIN R5 Dummy Shunt CF 10nF Compensated REFIN NOTE: R5 is a dummy shunt resistor equal to 4x RSHUNT to compensate for RSHUNT and provide best CMR. 20mV/div 20mV/div a) Internal difference amplifier with an example of a decoupling filter. 10µs/div 10µs/div b) VOUT of Figure 5a with R5 = 20Ω and CD = 100nF. c) VOUT of Figure 5a with R5 = 50Ω and CD = 10nF. Figure 5. Internal Difference Amplifier With Example of a Decoupling Filter OVER-RANGE COMPARATOR High peak current can overload the differential amplifier connected to the shunt. The OVER-RANGE pin, an open-drain output, indicates an over-voltage condition for the differential amplifier by pulling low. The output of this flag is suppressed for 3 µs, preventing unwanted triggering from transients and noise. This pin returns to high as soon as the overload condition is removed (external pull-up required to return the pin high). This ERROR flag not only provides a warning about a signal clipping condition, but is also a window comparator output for actively shutting off circuits in the system. The value of the shunt resistor defines the operating window for the current. It sets the ratio between the nominal signal and the trip level of the Over-Range flag. The trip current of this window comparator is calculated using the following example: With a 5 V supply, the output voltage swing is approximately ±2.45 V (load and supply voltage-dependent). The gain of 4 V/V allows an input swing of ±0.6125 V. Thus, the clipping current is IMAX = 0.6125 V/RSHUNT. See the differential amplifier curve of the Typical Characteristics, Output Voltage vs Output Current. The over-range condition is internally detected as soon as the amplifier exceeds its linear operating range, not just a set voltage level. Therefore, the error or the over-range comparator level is reliably indicated in fault conditions such as output shorts, low load or low supply conditions. As soon as the output cannot drive the voltage higher, the flag is activated. This configuration is a safety improvement over a voltage level comparator. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 19 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com NOTE: The internal resistance of the compensation coil may prevent high compensation current from flowing because of ICOMP driver overload. Therefore, the differential amplifier may not overload with this current. However, a fast rate of change of the primary current would be transmitted through transformer action and safely trigger the overload flag. VOLTAGE REFERENCE The precision 2.5 V reference circuit offers low drift (typically 10 ppm/K) and is used for internal biasing; it is also connected to the REFOUT pin. The circuit is intended as the reference point of the output signal to allow a bipolar signal around it. This output is buffered for low impedance and tolerates sink and source currents of ±5 mA. Capacitive loads can be directly connected, but generate ringing on fast load transients. A small series resistor of a few ohms improves the response, especially for a capacitive load in the range of 1 µF. Figure 6 shows the transient load regulation with 1 nF direct load. The reference source is part of the integrated circuit and referenced to GND2. Large current pulses driving the compensation coil can generate a voltage drop in the GND connection that would add on to the reference voltage. Therefore, a low impedance GND layout is critical to handle the currents and the high bandwidth of this IC. Test Circuit: ±5V 1nF 10mV/div 10kΩ REFOUT +2.5V 2.5µs/div Figure 6. Pulse Response Test Circuit and Scope Shot of Reference DEMAGNETIZATION Iron cores are not immune to residual (remanence) magnetism. The residual remanence can produce a signal offset error, especially after strong current overload, which goes along with high magnetic field density. Therefore, the DRV401 includes a signal generator for a demagnetization cycle. The digital control pin, DEMAG, starts this cycle on demand after this pin is held high for at least 25.6 µs. Shorter pulses are ignored. The cycle lasts for approximately 110 ms. During this time, the Error flag is asserted low to indicate that the output is not valid. When DEMAG is high during power-on, a demagnetization cycle immediately initiates (12 µs) after power-on (VDD > 4 V). Holding DEMAG low avoids this cycle at power-up (see the Power-On and Brownout section). The probe circuit is in normal operation and oscillates during the demagnetization cycle. The outputs PWM and PWM are active accordingly. A demagnetization cycle can be aborted by pulling DEMAG low, filtered by 25 µs to ignore glitches (see Figure 7). In a typical circuit, the DEMAG pin may be connected to the positive supply, which enables a degauss cycle every time the unit is powered on. The degauss cycle is based on an internal clock and counter logic. The maximum current is limited by the resistance of the connected coil in series with the shunt resistor. The DEMAG logic input requires a +5 V CMOS-compatible signal. 20 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 POWER-ON AND BROWNOUT Power-on is detected with the supply voltage going higher than 4 V at VDD1. When DEMAG is high, a degauss cycle is started (see Figure 7a). During this time the ERROR flag remains low, indicating the not ready condition. Maintaining DEMAG low prevents this cycle, and the DRV401 starts operation approximately 32 µs after power-up. If no probe error conditions are detected within four full cycles (that is, the probe half-periods are shorter than 32 µs and longer than 280 ns), the compensation driver starts and the ERROR pin indicates the ready condition by going high, typically about 42 µs after power-up. NOTE: An external pull-up resistor is required to pull the ERROR pin high. Both supply pins (VDD1 and VDD2) should not differ by more than 100 mV for proper device operation. They are normally connected together or separately filtered (see Layout Considerations). The DRV401 tests for low supply voltage with a brown-out voltage level of +4 V; proper power conditions must be supplied. Good power-supply and low ESR bypass capacitors are required to maintain the supply voltage during the large current pulses that the DRV401 can drive. A critical voltage level is derived from the proper operation of the probe driver. The probe interface relies on a peak current flowing through the probe to trip the comparator. The probe resistance plus the internal resistance of the driver (see Electrical Characteristics specification, Probe Coil Loop, Internal Resistor) sets the lower limit for the acceptable supply voltage. Voltage drops lasting less than 31 ms are ignored. The probe error detection activates the ERROR pin as soon as proper oscillation fails for more than 32 µs. A low supply voltage condition, or brown-out, is detected at +4 V. Short and light voltage drops of less than 100 µs are ignored, provided the probe circuit continues to operate. If the probe no longer operates, the ERROR pin goes active. Signal overload recovery is only provided if the probe loop was not discontinued. A supply drop lasting longer than 100 µs generates power-on reset. A voltage dip down to +1.8 V (for VDD1) also initiates a power-on reset. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 21 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com VDD1 5V/div V(ERROR) 106ms 1 4 V(ICOMP2) RSH = 10Ω 2V/div 2 VOUT 3 20ms/div a) Demagnetization cycle on power-up. With power-up, the VOUT across the compensation coil centers around half the supply and then starts the cycle after the 4V threshold is exceeded. The ERROR flag resets to H after the cycle is completed. VDD1 V(DEMAG) 42µs 1 5V/div 5V/div 1 V(ERROR) 4 4 106ms V(IS1) V(ERROR) V(ICOMP2) 2 V(ICOMP2) Initial setting upon closing of feedback loop. 3 RSH = 10Ω 2V/div 2V/div 2 VOUT 3 20ms/div 20ms/div c) Demagnetization cycle on command. b) Power-up without demagnetization. The probe oscillation V(IS1) starts just before ERROR resets — 15µs after the supply voltage crosses the 4V threshold. V(DEMAG) 5V/div 1 V(ERROR) 4 V(ICOMP2) RSH = 10Ω 2 2V/div 3.4ms VOUT 3 500µs/div d) Abort of demagnetization cycle. The ERROR flag resets to H (as shown) and the output settles back to normal operation. Figure 7. Demagnetization and Power-On Timing 22 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 ERROR CONDITIONS In addition to the Over-Range flag that indicates signal clipping in the output amplifier (differential amplifier), a system error flag is provided. The ERROR flag indicates conditions when the output voltage does not represent the primary current. It is active during a demagnetization cycle, during a power-fail or brown-out. It also goes active with an open or short-circuit in the probe loop. As soon as the error condition is no longer present and the circuit has returned to normal operation, the flag resets. Both the ERROR and Over-Range flags are open-drain logic outputs. They can be connected together for a wired-OR and require an external pull-up resistor for proper operation. The following conditions result in ERROR flag activation (ERROR asserts low): 1. The probe comparator stays low for more than 32 µs. This condition occurs either if the probe coil connection is open or if the supply voltage dips to the level where the required saturation current cannot be reached. During the 32 µs timeout, the ICOMP driver remains active but goes inactive thereafter. In case of recovery, ERROR is low and the ICOMP driver remains in reset for another 3.3 ms. 2. The probe driver pulse-width is less than 280 ns for three consecutive periods. This condition indicates either a shorted field probe coil or a fully-saturated sensor at start-up. If this condition persists longer than 25 µs and then recovers, the ERROR flag remains low and ICOMP is in reset for another 3.3 ms. If the condition lasts less than 25 µs, the ERROR flag recovers immediately and the ICOMP driver is not interrupted. 3. During demagnetization, if the cycle is aborted early by pulling DEMAG low, the ERROR flag stays low for another 3.3 ms (ICOMP is disabled during this time). 4. An open compensation coil is detected (longer than 100 µs). Note: the probe driver, the PWM signal filter and the ICOMP driver continue to function in normal mode—only the ERROR flag is asserted in this case. This condition indicates that not enough current is flowing in the ICOMP driver output; this condition might be the result of a high-resistance compensation coil or the connection of an external driver. Detection of this condition can be disabled by setting the CCdiag pin low. 5. At power-on after VDD1 crosses the +4 V threshold, the ERROR flag is low for approximately 42 µs. 6. A supply voltage low (brown-out) condition lasts longer than 100 µs. Recovery is the same as power-up, either with or without a demag cycle. PROTECTION RECOMMENDATIONS The inputs IAIN1 and IAIN2 require external protection to limit the voltage swing beyond 10 V of the supply voltage. The driver outputs ICOMP1 and ICOMP2 can handle high current pulses protected by internal clamp circuits to the supply voltage. If repeated over-currents of large magnitudes are expected, connect external Schottky diodes to the supply rails. This external protection prevents current flowing into the die. The probe connections IS1 and IS2 are protected with diode clamps to the supply rails. In normal applications, no external protection is required. The maximum current must be limited to ±75 mA. All other pins offer standard protection-see the Absolute Maximum Ratings table. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 23 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com BASIC CONNECTION EXAMPLE The circuit shown in Figure 8 offers an axample of a fully-connected current sensor system. IP Primary Winding Current Sensor Module Probe Core Main Core Probe Coil S1 Compensation Coil K1 S2 K2 +5V IS2 ICOMP R3 R4 C4 D1 C3 R2 D2 R1 +5V IS1 IS2 PWM GAIN PWM CCdiag ICOMP1 ICOMP2 (PWM is in phase with IS1.) +5V VDD1 C2 Probe Coil Driver and Comparator IAIN2 IAIN1 Amp V=4 +5V R6 Integrator OVER−RANGE H−Bridge Driver VSW R5 GND1 VOUT REFIN VSW 2.5V Bandgap Reference REFOUT 10MHz DEMAG Logic: Timing, Error Detection, and Demagnetize Oscillator Reset Power Valid DRV401 R7 ERROR VDD2 GND2 C4 +5V +5V Figure 8. Basic Connection Circuit 24 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 The connection example in Figure 8 illustrates the few external components required for optimal performance. Each component is described in the following list: • IP is the primary current to be measured; K1 and K2 connect to the compensation coil. S1 and S2 connect to the magnetic field probe. The dots indicate the winding direction on the sensor main core. • R1 and R2 form the shunt resistor RSHUNT. This resistance is split into two to allow for adjustments to the required RSHUNT value. The accuracy and temperature stability of these resistors are part of the final system performance. • R3 and R4, together with C3 and C4, form a network that reduces the remaining probe oscillator ripple in the output signal. The component values depend on the sensor type and are tailored for best results. This network is not required for normal operation. • R5 is the dummy shunt (RD) resistor used to restore the symmetry of both differential amplifier inputs. R5 = 4 × RSHUNT, but the accuracy is less important. • R6 and R7 are pull-up resistors connected to the logic outputs. • C1 and C2 are decoupling capacitors. Use low ESR-type capacitors connected close to the pins. Use low impedance printed circuit board (PCB) traces, either avoiding vias (plated-through holes) or using multiple vias. A combination of a large(> 1 µF) and a small (< 4.7 nF) capacitor are suggested. When selecting capacitors, make sure to consider the large pulse currents handled from the DRV401. • D1 and D2 are protection diodes for the differential amplifier input. They are needed only if the voltage drop at RSHUNT exceeds 10 V at the maximum possible peak current. LAYOUT CONSIDERATIONS The DRV401 operates with relatively large currents and fast current pulses, and offers wide-bandwidth performance. It is often exposed to large distortion energy from both the primary signal and the operating environment. Therefore, the wiring layout must provide shielding and low-impedance connections between critical points. Use low ESR capacitors for power-supply decoupling. Use a combination of a small capacitor and a large capacitor of 1 µF or larger. Use low-impedance tracks to connect the capacitors to the pins. Both grounds should be connected to a local ground plane. Both supplies can be connected together; however, best results are achieved with separate decoupling (to the local GND plane) and ferrite beads in series with the main supply. The ferrite beads decouple the DRV401, reducing interaction with other circuits powered from the same supply voltage source. The reference output is referred to GND2. A low-impedance, star-type connection is required to avoid the driver current and the probe current modulating the voltage drop on the ground track. The connection wires of the difference amplifier to the shunt must be low resistance and of equal length. For best accuracy, avoid current in this connection. Consider using a Kelvin Contact-type connection. The required resistance value can be set using two resistors. Wires and PCB traces for S1 and S2 should be very close or twisted. ICOMP1 and ICOMP2 should also be wired close together. To avoid capacitive coupling, run a ground shield between the S1/S2 and ICOMP wire pair or keep them distant from each other. The compensation driver outputs (ICOMP) are low frequency only; however, the primary signal (with high-frequency content present) is coupled into the compensation winding, the shunt, and the difference amplifier. Therefore, careful layout is recommended. The output of REFOUT and VOUT can drive some capacitive loads, but avoid large direct capacitive loads; these loads increase internal pulse currents. Given the wide bandwidth of the differential amplifier, isolate any large capacitive load with a small series resistor. A small capacitor in the pF range can improve the transient response on a high resistive load. The exposed thermal pad on the bottom of the package must be soldered to GND because it is internally connected to the substrate, which must be connected to the most negative potential. It is also necessary to solder the exposed pad to the PCB to provide structural integrity and long-term reliability. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 25 DRV401-EP SBVS104 – JANUARY 2008............................................................................................................................................................................................... www.ti.com POWER DISSIPATION Using the thermally-enhanced PowerPAD™ SO package dramatically reduces the thermal impedance from junction to case. This package is constructed using a down-set lead frame upon which the die is mounted, as shown in Figure 9a and Figure 9b. This arrangement results in the lead frame being exposed as a thermal pad on the underside of the package. Figure 9 shows the SO-20 package as an example. Because this thermal pad has direct thermal contact with the die, excellent thermal performance can be achieved by providing a good thermal path away from the thermal pad. The two outputs ICOMP1 and ICOMP2 are linear outputs. Therefore, the power dissipation on each output is proportional to the current multiplied by the internal voltage drop on the active transistor. For ICOMP1 and ICOMP2, this internal voltage drop is the voltage drop to VDD2 or GND, according to the current-conducting side of the output. Output short-circuits are particularly critical for the driver because the full supply voltage can be seen across the conducting transistor, and the current is not limited by anything other than the current density limitation of the FET. Permanent damage to the device can occur. The DRV401 does not include temperature protection or thermal shut-down. THERMAL PAD Packages with an exposed thermal pad are specifically designed to provide excellent power dissipation, but board layout greatly influences overall heat dissipation. Table 1 shows the thermal resistance (TJA) for the two packages with the exposed thermal pad soldered to a normal PCB, as described in Technical Brief SLMA002, PowerPAD Thermally-Enhanced Package. Documents are available for download at www.ti.com. Table 1. θJA/JP Estimations According to EIA/JED51-7 SO–20 θJP (1) 9 θJA (2) Still Air 35 θJA with Forced Airflow (150lfm (3)) 32 (1) (2) (3) θJP = junction-to-pad thermal resistance, θJA = junction-to-ambient thermal resistance, lfm = linear foot per minute. NOTE: All thermal models have an accuracy 9≈20%. Measuring the temperature as close as possible to the exposed thermal pad is recommended. The relatively low thermal impedance, θJP, of less than 10°C/W (with some additional °C/W to the temperature test point on the PCB) allows good estimation of the junction temperature in the application. The thermal pad on the PCB should contain nine or more vias for the SO package, where the solder pad on the PCB can be larger than the exposed pad (for example, 6.6 mm × 18 mm) as recommended in the application literature noted previously. Component population, layout of traces, layers, and air flow strongly influence heat dissipation. Worst-case load conditions should be tested in the real environment to ensure proper thermal conditions. Minimize thermal stress for proper long-term operation with a junction temperature well below +125°C. 26 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP DRV401-EP www.ti.com............................................................................................................................................................................................... SBVS104 – JANUARY 2008 DIE Side View (a) Exposed Thermal Pad DIE Bottom View (c) End View (b) Figure 9. SO-20 Package Example of Thermally Enhanced PowerPAD Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): DRV401-EP 27 PACKAGE OPTION ADDENDUM www.ti.com 28-Jul-2008 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty DRV401AMDWPREP ACTIVE SO Power PAD DWP 20 1000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR V62/08630-01XE ACTIVE SO Power PAD DWP 20 1000 Green (RoHS & no Sb/Br) CU NIPDAU Level-2-260C-1 YEAR Lead/Ball Finish MSL Peak Temp (3) (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. TBD: The Pb-Free/Green conversion plan has not been defined. Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above. Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material) (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. 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Addendum-Page 1 PACKAGE MATERIALS INFORMATION www.ti.com 23-Jul-2008 TAPE AND REEL INFORMATION *All dimensions are nominal Device DRV401AMDWPREP Package Package Pins Type Drawing SO Power PAD DWP 20 SPQ Reel Reel Diameter Width (mm) W1 (mm) 1000 330.0 24.4 Pack Materials-Page 1 A0 (mm) B0 (mm) K0 (mm) P1 (mm) W Pin1 (mm) Quadrant 10.8 13.0 2.7 12.0 24.0 Q1 PACKAGE MATERIALS INFORMATION www.ti.com 23-Jul-2008 *All dimensions are nominal Device Package Type Package Drawing Pins SPQ Length (mm) Width (mm) Height (mm) DRV401AMDWPREP SO PowerPAD DWP 20 1000 346.0 346.0 41.0 Pack Materials-Page 2 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services at any time and to discontinue any product or service without notice. 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