ADA4570WHRZ-R7

Data Sheet ADA4570 Integrated AMR Angle Sensor and Signal Conditioner with Differential Outputs FEATURES ► ► ► ► ► ► ► ► ► ► ► ► ► ► ► ► ► ► FUNCTIONAL BLOCK DIAGRAM Contactless angular measurement High precision 180° angle sensor Typical angular error of ±0.1° Low output noise of 850 μV rms Sine and cosine differential outputs Ratiometric analog voltage outputs Negligible hysteresis SAR or Σ-Δ ADC compatible Temperature compensated AMR bridge Industrial temperature range: −40°C to +125°C Automotive temperature range: −40°C to +150°C EMI resistant Fault diagnostics VDD from 2.7 V to 5.5 V Minimal phase error of 0.85° at 30,000 rpm AEC-Q100 qualified for automotive applications Single chip solution Available in an 8-lead SOIC package APPLICATIONS ► ► ► ► ► Absolute position measurement (linear and angle) Brushless dc motor control and positioning Actuator control and positioning Contactless angular measurement and detection Magnetic angular position sensing Figure 1. GENERAL DESCRIPTION The ADA4570 is an anisotropic magnetoresistive (AMR) sensor with integrated signal conditioning amplifiers and analog-to-digital converter (ADC) drivers. The ADA4570 produces two differential analog outputs that indicate the angular position of the surrounding magnetic field. The ADA4570 consists of two die within one package, an AMR sensor, and a fixed gain instrumentation amplifier. The ADA4570 delivers amplified differential cosine and sine output signals, with respect to the angle, when the magnetic field is rotating in the x-axis and the y-axis (x-y) plane. The output voltage range is ratiometric to the supply voltage. The sensor contains two Wheatstone bridges, at a relative angle of 45° to one another. A complete rotation of a dipole magnet produces two periods on the sinusoidal outputs. Therefore, the magnetic angle (α) calculated from the SIN and COS differential outputs represents the physical orientation of the magnet with respect to the ADA4570 in the 0° to 180° measurement range. Within a homogeneous field in the x-y plane, the output signals of the ADA4570 are independent of the physical placement in the z direction (air gap). The ADA4570 is available in an 8-lead SOIC package. Rev. 0 DOCUMENT FEEDBACK TECHNICAL SUPPORT Information furnished by Analog Devices is believed to be accurate and reliable "as is". However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. Data Sheet ADA4570 TABLE OF CONTENTS Features................................................................ 1 Applications........................................................... 1 Functional Block Diagram......................................1 General Description...............................................1 Specifications........................................................ 3 Absolute Maximum Ratings...................................5 Electrostatic Discharge (ESD) Ratings...............5 Thermal Resistance........................................... 5 ESD Caution.......................................................5 Pin Configuration and Function Descriptions........ 6 Typical Performance Characteristics..................... 7 Terminology........................................................... 9 Theory of Operation.............................................10 Applications Information...................................... 11 Supply and ADC Reference............................. 11 Connecting the ADA4570................................. 11 Angle Calculation..............................................11 Signal Dependence on Air Gap Distance ........ 11 Signal Offset and Calibration............................11 VTEMP Output Pin .......................................... 12 Power Consumption ........................................ 12 Diagnostic.........................................................12 Outline Dimensions............................................. 13 Ordering Guide.................................................13 Automotive Products........................................ 14 REVISION HISTORY 7/2021—Revision 0: Initial Version analog.com Rev. 0 | 2 of 14 Data Sheet ADA4570 SPECIFICATIONS VDD = 2.7 V to 5.5 V, differential load capacitance (CL) = 22 nF, load resistance (RL ) = 200 kΩ to GND. The operating temperature range (OTR) for the ADA4570B is −40°C ≤ TA ≤ +125°C and for the ADA4570WH is −40°C ≤ TA ≤ +150°C. The angle inaccuracies referred to the homogenous magnetic field with a minimum flux density of 30 mT. All listed environmental conditions are valid, unless otherwise stated. Table 1. Parameter Min MAGNETIC CHARACTERISTICS Magnetic Flux Density, BEXT 30 Magnetic Field Rotational Frequency Reference Position Error Reference Angle Error ANGULAR PERFORMANCE Angle Measurement Range Uncorrected Angular Error1 (αUNCORR) ADA4570B/ADA4570WH ADA4570WH Single Point Calibration Angular Error2 (αCAL) ADA4570B/ADA4570WH ADA4570WH Dynamic Angular Error3, 4 (αDYNAMIC) ADA4570B/ADA4570WH ADA4570WH OUTPUT PARAMETERS Differential Peak Amplitude (VAMP) ADA4570B/ADA4570WH analog.com Max Unit Test Conditions/Comments mT The stimulating magnetic flux density in the x-y sensor plane necessary to ensure operation within specified limits 50,000 ±50 ±2 rpm μm Degrees 180 Degrees ±3 ±3 ±4 ±5 Degrees Degrees Degrees Degrees TA = −40°C TA = 25°C TA = 125°C TA = 150°C Degrees Degrees TA = −40°C to +125°C TA = −40°C to +150°C ±0.4 ±0.5 Degrees Degrees TA = −40°C to +125°C TA = −40°C to +150°C 77 72 57 55 93 % VDD % VDD % VDD % VDD % VDD TA = −40°C TA = 25°C TA = 125°C TA = 150°C 3.75 5 % VDD % VDD TA = −40°C to +125°C TA = −40°C to +150°C 3.75 3.9 101 TA = −40°C to +125°C TA = −40°C to +150°C Differential measurement 850 % VDD % VDD % peak µs Degrees Degrees µV rms 60 175 80 Ω kHz dB 0 56 52 38 ADA4570WH 35 Single-Ended Output Voltage Range5 (VO_SWING) 7 Single-Ended Output Voltage Low5, 6 (VOL) ADA4570B/ADA4570WH ADA4570WH Differential Output Referred Offset Voltage (VOFFSET) ADA4570B/ADA4570WH ADA4570WH Amplitude Synchronism7 (k) 99 Amplifier Propagation Delay8 (tDEL) Phase Error8, 9 (ΦERR) Orthogonality Error Output Noise (VNOISE) Output Series Resistance (RO) Output −3 dB Cutoff Frequency (f−3dB) Power Supply Rejection (PSRR) Typ ±0.5 ±0.7 ±0.1 ±0.1 2.35 0.85 ±0.05 Bandwidth = 80 kHz, referred to output (RTO) Amplifier bandwidth, CL = 10 pF Measured as output variation from VDD/2, VDD = 5.0 V, TA= 25°C Rev. 0 | 3 of 14 Data Sheet ADA4570 SPECIFICATIONS Table 1. Parameter Min Output Short-Circuit Current10 (ISC) POWER SUPPLY Supply Voltage Range (VDD) Supply Current Range (IDD) Power-Up Time (tPWRUP) TEMPERATURE SENSOR Error Over Temperature (TERR) Temperature Voltage Range (TRANGE) Temperature Coefficient (TCO) VTEMP Output Voltage Range VTEMP Output Impedance VTEMP Load Capacitance VTEMP Short-Circuit Current (ISC_VTEMP) 2.7 2.9 Unit Test Conditions/Comments 15 Typ mA 16 mA Short to GND per output pin, VDD = 5.0 V, TA = 25°C Short to VDD per output pin, VDD = 5.0 V, TA = 25°C 4.5 Max 5.5 6.3 150 5 600 22 3 °C % VDD mV/V/°C % VDD Ω nF mA 22 nF 0 82 3.173 18 LOAD CAPACITOR External Differential Load Capacitance11 (CL) V mA μs 40 No load The time measured between VDD reaching 90% of the supply voltage and angular measurement result being within 2° of the final angle TA = −40°C to +150°C TA = 25°C Buffered output Optional load capacitance Short-circuit to GND, VDD = 5.0 V, TA = 25°C 1 αUNCORR is the total mechanical angular error after the arctan computation. This error includes all sources of error over temperature before calibration. Error components such as offset, amplitude synchronism, amplitude synchronism drift, thermal offset drift, phase error, hysteresis, orthogonality error, and noise are included. 2 αCAL is the total mechanical angular error after the arctan computation. This error includes all sources of error over temperature after an initial offset (nulling) is performed at TA = 25°C. Error components such as amplitude synchronism drift, amplifier gain matching, thermal offset drift, phase error, hysteresis, orthogonality error, and noise are included. 3 Magnetic field rotation frequency = 1000 rpm. 4 αDYNAMIC is the total mechanical angular error after the arctan computation. This error includes all sources of error over temperature after a continuous background calibration is performed to correct offset and amplitude synchronism errors. Error components such as phase error, hysteresis, orthogonality error, noise, and lifetime drift are included. 5 Applies to the VSIN+, VSIN−, VCOS+, and VCOS− outputs. 6 Broken bond wire detected. 7 Peak-to-peak amplitude matching. k = 100 × VSIN/VCOS. 8 Magnetic field rotation frequency = 30000 rpm. 9 Rotation frequency dependent phase error after offset correction, amplitude calibration, and arctan calculation. 10 The short-circuit condition specified is present for each output at the following mechanical angles: short to VDD with VSIN+ at α = 135°, VSIN− at α = 45°, VCOS+ at α = 0°, and VCOS− at α = 90° and short to GND with VSIN+ at α = 45°, VSIN− at α = 135°, VCOS+ at α = 9°, and VCOS− at α = 0°. 11 Solder CL/4 between VSIN+ and VSIN− and between VCOS+ and VCOS−. Solder CL/2 between VSIN+ to GND, VSIN− to GND, VCOS+ to GND, and VCOS− to GND. Solder close to package. analog.com Rev. 0 | 4 of 14 Data Sheet ADA4570 ABSOLUTE MAXIMUM RATINGS Table 2. Parameter Temperature Operating Range ADA4570B ADA4570WH Storage Range Supply Voltage (VDD) Table 3. ADA4570, 8-Lead SOIC_N Rating −40°C to +125°C −40°C to +150°C −65°C to +150°C −0.3 V to +6 V Stresses at or above those listed under Absolute Maximum Ratings may cause permanent damage to the product. This is a stress rating only; functional operation of the product at these or any other conditions above those indicated in the operational section of this specification is not implied. Operation beyond the maximum operating conditions for extended periods may affect product reliability. ESD Model Withstand Threshold (V) HBM CDM 4000 1250 THERMAL RESISTANCE Thermal performance is directly linked to printed circuit board (PCB) design and operating environment. Careful attention to PCB thermal design is required. θJA is the junction to ambient temperature, and θJC is the junction to case temperature. Table 4. Thermal Resistance Package Type1 θJA θJC Unit R-8 120 39 °C/W ELECTROSTATIC DISCHARGE (ESD) RATINGS 1 The following ESD information is provided for handling of ESD-sensitive devices in an ESD protected area only. ESD CAUTION Human Body Model (HBM) tested according to standard JESD22C101. Charge Device Model (CDM) tested according to standard ESDA/JEDEC JS-001-2011. analog.com Thermal performance per JEDEC defined (JESD-51) test specifications. ESD (electrostatic discharge) sensitive device. Charged devices and circuit boards can discharge without detection. Although this product features patented or proprietary protection circuitry, damage may occur on devices subjected to high energy ESD. Therefore, proper ESD precautions should be taken to avoid performance degradation or loss of functionality. Rev. 0 | 5 of 14 Data Sheet ADA4570 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS Figure 2. Pin Configuration Table 5. Pin Function Descriptions Pin No. Mnemonic Description 1 2 3 4 5 6 7 8 VCOS− VTEMP VSIN− RSVD VSIN+ VDD VCOS+ GND Analog Negative Cosine Output. Analog Temperature Output. The VTEMP pin must be left open when not in use. Analog Negative Sine Output. Reserved. The RSVD pin must be connected to GND. Analog Positive Sine Output. Power Supply. Analog Positive Cosine Output. Ground. analog.com Rev. 0 | 6 of 14 Data Sheet ADA4570 TYPICAL PERFORMANCE CHARACTERISTICS Figure 3. Differential Output Amplitude vs. Relative Mechanical Angle Figure 6. Single Point Calibration Angular Error vs. Temperature Figure 4. Uncorrected Angular Error Histogram Figure 7. Dynamic Angular Error Histogram Figure 5. Angular Error vs. Mechanical Angle After Offset Correction Figure 8. Supply Current vs. Supply Voltage analog.com Rev. 0 | 7 of 14 Data Sheet ADA4570 TYPICAL PERFORMANCE CHARACTERISTICS Figure 9. VTEMP Output Voltage vs. Temperature Figure 12. Phase Error vs. Mechanical RPM Figure 10. Amplitude Synchronism Histogram Figure 13. Frequency Response Figure 11. Differential Output Peak-to-Peak vs. Temperature analog.com Rev. 0 | 8 of 14 Data Sheet ADA4570 TERMINOLOGY Output Signals The output signals, VSIN+, VSIN−, VCOS+, and VCOS−, of the ADA4570 are biased around a common-mode voltage of VDD/2 as shown in Figure 14. Figure 16. Sensor Alignment in Package Uncorrected Angular Error The uncorrected angular error is defined as the maximum deviation from an ideal angle without any calibration applied to the VSIN and VCOS differential signals. Single Point Calibration Angular Error The single point calibration angular error is defined as the deviation from an ideal angle after the offset calibration is applied to the VSIN and VCOS differential signals at 25°C. Dynamic Angular Error Figure 14. Single-Ended Output Voltage Range The differential signal outputs, VSIN and VCOS, shown in Figure 15 are generated by sampling the corresponding positive and negative SIN and COS single-ended outputs. The dynamic angular error is defined as the maximum deviation from an ideal angle with the continuous offset and gain calibration applied to the VSIN and VCOS differential signals. Output Amplitude Synchronism The output amplitude synchronism (k) is defined as the ratio between the differential amplitudes of both channels when under a continuously rotating magnetic field. To calculate the amplitude synchronism, use the following equations: k = 100% × VAMP(VSIN)/VAMP(VCOS) Propagation Delay The propagation delay is the amount of time taken for the signal to propagate to the VSIN and VCOS differential signal outputs in response to a magnetic stimulus change. Phase Error Figure 15. Differential Output Voltage Range The phase error is defined as the average of the phase shift in the sine and cosine signal through the amplifier. The phase error increases with the rotation frequency due to the bandwidth limitation of the instrumentation amplifiers. As shown in Figure 12, the typical characteristics value can be used as a first-order compensation for the phase error. Reference Position Error Orthogonality Error The reference position error is the deviation of the sensing element center from the nominal position shown in Figure 22. The orthogonality error is the internal phase error caused by misalignment of the sine and cosine sensor elements on-chip, with respect to the ideal 90° sine to cosine phase. Reference Angle Error The reference angle error, indicated in Figure 16, is the absolute mounting angle error of the sensor from its nominal placement. The angle Φ = 0° is referred to the straight line between the top of Pin 2 and Pin 7. analog.com Single-Ended Output Voltage Low The single-ended output voltage low is the maximum voltage level at the VSIN+, VSIN−, VCOS+, and VCOS− outputs when a broken bond wire is detected and all outputs are pulled low, see Figure 14. Rev. 0 | 9 of 14 Data Sheet ADA4570 THEORY OF OPERATION As shown in the Figure 1, the ADA4570 contains all the necessary peripherals for AMR angle sensing of a magnetic field in the x-y plane of the sensor. The bridge driver provides the voltage supply to the AMR sensor. The sensitivity of AMR sensor is temperature dependent, and the bridge driver is designed to provide a supply voltage that compensates for the temperature dependence (see Figure 17). Figure 17. Temperature Compensated Bridge Driver The ADA4570 consists of two dies that are connected internally by bond wires, the AMR sensor and an application specific IC (ASIC) that incorporates the electronics required to condition the output signals. A broken bond wire detection system was implemented in the ASIC that detects if any of the bond wires between the AMR bridge and ASIC become detached or broken. Note that when a broken bond wire is detected, the VSIN and VCOS differential signal outputs are forced low. Electromagnetic interference (EMI) filters are implemented at the AMR sensor outputs to prevent unwanted noise and interference from appearing in the signal band of the input to the instrumentation amplifier. The architecture of the instrumentation amplifier consists of precision, low noise, zero drift amplifiers that feature a proprietary chopping technique. This chopping technique offers a low input offset voltage as well as a low input offset voltage drift. The zero drift design also features chopping ripple suppression circuitry that removes glitches and other artifacts caused by chopping. Offset voltage errors caused by common-mode voltage swings and power supply variations are also corrected by the chopping technique, resulting in a very high dc common-mode rejection ratio. The amplifiers feature a low broadband noise of 33 nV/√Hz and no 1/f noise component. These features are ideal for amplification of the low level AMR bridge signals for high precision sensing applications. The differential amplifier outputs, VSIN and VCOS, are capable of driving the inputs of an external ADC without requiring any additional signal conditioning, as shown in Figure 18. Figure 18. Typical Application Diagram analog.com Rev. 0 | 10 of 14 Data Sheet ADA4570 APPLICATIONS INFORMATION The ADA4570 is designed for magnetoresistive sensing applications with a differential analog output. The sensor is designed to operate with an external ADC that is controlled by a separate processing IC or electronic control unit (ECU) as indicated in Figure 18. SUPPLY AND ADC REFERENCE Connect a decoupling capacitance of 100 nF to the ADA4570 VDD supply pin to minimize interferences on the power supply from entering the system. To achieve optimum power supply related noise performance, connect the VDD supply of the ADA4570 as the voltage reference of the ADC, as shown in Figure 18. Using the ADA4570 VDD supply as the reference input voltage to the external ADC provides a ratiometric configuration where the output dependency on the supply voltage changes is minimized. This configuration also optimizes the use of the ADC input range because the output voltages of the VSIN+, VSIN−, VCOS+, and VCOS− pins track the supply voltage. CONNECTING THE ADA4570 Figure 19. Direction of Homogeneous Magnetic Field for α = 0° SIGNAL DEPENDENCE ON AIR GAP DISTANCE The ADA4570 measures the direction of the external magnetic field within the sensor x-y plane. Within a homogeneous field in the xy direction, where the magnetic flux density is at least 30 mT, the accuracy and voltage levels of the angular measurement is independent of the field strength and the sensor placement in z direction (air gap). The nominal z distance of the internal x-y plane to the top surface of the plastic package is shown in Figure 22. A typical circuit to connect the ADA4570 to a differential ADC is shown in Figure 18. The ADA4570 signal driving capability is sufficient to connect the analog outputs directly to a differential successive approximation register (SAR) or a Σ-Δ ADC. SIGNAL OFFSET AND CALIBRATION Minimize the signal trace lengths to the ADC or the processing IC. Using proper layout techniques and ground planes around the analog signal tracks provides shielding on the PCB and improves electromagnetic compatibility (EMC) robustness. For each differential output, the load resistor (RL) and the single-ended load capacitance (CL/2) must refer to ground, and the differential load capacitance (CL/4) must be connected between the differential outputs (see Figure 18.). The load resistors and capacitors must match to achieve the best angular accuracy. In addition, take the desired system sampling frequency into account when adding noise reducing filters to the front of the ADC. Matching inaccuracies and other imperfections during the production process may result in offsets in the outputs. To minimize additional offsets, caused by the external filter components, match the external capacitive and resistive loads to each other by using the same nominal values for the external components connected to VSIN+, VSIN−, VCOS+, and VCOS−. ANGLE CALCULATION The angle of the incident magnetic field is calculated from the output of the ADA4570, and the trigonometric function arctangent(2) (arctan2) is used. To calculate the ADA4570 output angle, use the following equation: α = arctan2(VSIN/VCOS)/2 With the sensing range of the AMR sensor, the calculated angle repeats every 180° rotation of the magnetic field. For a dipole magnet, the ADA4570 reports an angle with twice the frequency of the rotation. The ADA4570 provides two differential output signals, VSIN and VCOS, with an output voltage range of ±VAMP (see Figure 15). To calculate the offset, use the positive and negative VAMP value of a full magnetic rotation as follows: VOFFSET = (VAMP_POS + VAMP_NEG)/2 The VSIN and VCOS output offset can be removed by subtracting the calculated offsets VOFFSET(VSIN)and VOFFSET(VCOS) from the VSIN and VCOS measurement result. A single point calibration is usually done at 25°C and removes the system offset at this temperature. This simple calibration does not take temperature related offset drifts into account that may be caused by drifts within the internal or external components. This calibration may be sufficient for many applications in particular where no large changes in temperature are expected. To compensate for offset drifts over the full temperature range, dynamic offset calibrations are required. The direction of a homogeneous magnetic field for an angle of α = 0°is shown in Figure 19 analog.com Rev. 0 | 11 of 14 Data Sheet ADA4570 APPLICATIONS INFORMATION VTEMP OUTPUT PIN An internal temperature sensor provides a voltage output at the VTEMP pin that can be used to monitor the operating temperature of the system and provide the reference for calibration. This output voltage (VTEMP) is ratiometric to the ADA4570 supply voltage. Using an ADC, the reference of which is supplied by the VDD of the ADA4570, ensures that the digitized temperature measurement is also ratiometric. To achieve maximum accuracy from the VTEMP output voltage, perform an initial calibration at a known and controlled temperature. To calculate the temperature, use the following equation: VTEMP − VCAL − TCAL × TCO VDD TCO Figure 20. Short-Circuit Diagnostic Band Short-Circuit Diagnostic Bands TVTEMP is the calculated temperature (°C) from the VTEMP output voltage. The output levels of the ADA4570 were designed to be within the linear region shown in Figure 20 during normal operation. Validate that the output levels are within the appropriate operating band. If any, or all, of the VSIN+, VSIN−, VCOS+, and VCOS− outputs are in the diagnostic bands, the outputs must be treated at the system level because this is an indication of a potential fault. VTEMP is the VTEMP output voltage during operation. Radius Calculation VCAL is the VTEMP output voltage during calibration at a controlled temperature. The differential signal outputs, VSIN and VCOS, from the ADA4570 can be used to calculate a radius (VRAD) of the circle at any angle of the applied magnetic field, as is shown in Figure 21. TVTEMP = where: (1) TCAL is the controlled temperature during calibration. TCO is the temperature coefficient of the internal circuit. See the Specifications section for the exact value. VDD is the supply voltage. In Figure 18, an optional resistor is shown in the VTEMP signal path to the ADC. When operating in a harsh environment, this resistor increases device immunity to EMI. POWER CONSUMPTION The power consumption is dependent on the supply voltage and temperature as shown in Figure 8. The analog outputs are protected against short circuit to the VDD pin or ground by a current limitation. DIAGNOSTIC Broken Bond Wire Detection The ADA4570 includes the ability to detect broken bond wires between the AMR sensor and the ASIC. When this circuitry detects that the signal nodes are outside the normal operating region, the device pulls the VSIN+, VSIN−, VCOS+, and VCOS− analog output pins to ground. Monitor the voltage level of the analog signals to verify that the output level does not fall within the short-circuit diagnostic band shown in Figure 20. If the outputs fall within the short-circuit diagnostic band shown in Figure 20, the user must take the appropriate action. analog.com Figure 21. Radius Values VRAD is equal to the vector sum of the differential signal outputs, VSIN and VCOS. VRAD   =   VSIN2   +   VCOS2 Due to the constant phase difference of 90° between the measurements of the differential signal outputs, VSIN and VCOS, VRAD is constant over an entire magnetic revolution for a constant temperature and supply. It is important to perform an offset calibration before a radius calculation is done. Rev. 0 | 12 of 14 Data Sheet ADA4570 OUTLINE DIMENSIONS Figure 22. 8-Lead Standard Small Outline Package [SOIC_N] Narrow Body (R-8) Dimensions Shown in Millimeters ORDERING GUIDE Model1 Temperature Range Package Description Package Option ADA4570BRZ ADA4570BRZ-R7 ADA4570BRZ-RL ADA4570WHRZ ADA4570WHRZ-R7 ADA4570WHRZ-RL EVAL-ADA4570SDZ −40°C to +125°C −40°C to +125°C −40°C to +125°C −40°C to +150°C −40°C to +150°C −40°C to +150°C 8-Lead Standard Small Outline Package [SOIC_N] 8-Lead Standard Small Outline Package [SOIC_N] 8-Lead Standard Small Outline Package [SOIC_N] 8-Lead Standard Small Outline Package [SOIC_N] 8-Lead Standard Small Outline Package [SOIC_N] 8-Lead Standard Small Outline Package [SOIC_N] ADA4570 Evaluation Board R-8 R-8 R-8 R-8 R-8 R-8 1 Z = RoHS-Compliant Part. analog.com Rev. 0 | 13 of 14 Data Sheet ADA4570 OUTLINE DIMENSIONS AUTOMOTIVE PRODUCTS The ADA4570W models are available with controlled manufacturing to support the quality and reliability requirements of automotive applications. Note that these automotive models may have specifications that differ from the commercial models; therefore, designers should review the Specifications section of this data sheet carefully. Only the automotive grade products shown are available for use in automotive applications. Contact your local Analog Devices account representative for specific product ordering information and to obtain the specific Automotive Reliability reports for these models. ©2021 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. One Analog Way, Wilmington, MA 01887-2356, U.S.A. Rev. 0 | 14 of 14