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| ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS 1 2 3 4 The ATS610LSA and ATS611LSB gear-tooth sensors are optimized Hall IC plus magnet modules that provide a user-friendly solution for digital gear-tooth sensing applications. Each module combines in a compact high-temperature plastic package, a samarium-cobalt magnet, a pole piece, and a differential Hall-effect IC that has been optimized to the magnetic circuit. These sensors can be easily used in conjunction with a wide variety of gear or target shapes and sizes. The ATS610LSA is designed to provide increased immunity to false switching in applications that require the sensing of large-tooth gears (e.g., crank angle or cam angle). The ATS611LSB is optimized to sense fine-pitch gears over large working air gaps (e.g., transmission or ABS). These sensors are ideal for use in gathering speed, position, and timing information using gear-tooth-based configurations. The gear-sensing technology used for these sensor plus magnet modules is Hall-effect based. The sensor incorporates a dual-element Hall IC that switches in response to differential magnetic signals created by the ferrous target. The circuitry contains a patented track-and-hold peak-detecting circuit to eliminate magnet and system offset effects. This circuit has the ability to detect relatively fast changes, such as those caused by gear wobble and eccentricities, and provides stable operation at extremely low rotation speeds. continued next page... Data Sheet 27627.100 Pin 1 = Supply Pin 2 = Output Pin 3 = Capacitor Pin 4 = Ground Dwg. AH-006 ABSOLUTE MAXIMUM RATINGS over operating temperature range Supply Voltage, VCC ......................... 16 V* Reverse Supply Voltage, VRCC ....... -0.5 V Output OFF Voltage, VOUT ................. 18 V Reverse Output Voltage, VOUT ....... -0.5 V Continuous Output Current, IOUT ... 25 mA Minimum External Capacitance, C3 ............................................. 0.1 F Package Power Dissipation, PD .................................... See Graph Operating Temperature Range, TA ........................... -40C to +150C* Storage Temperature, TS ............ +170C * Operation at increased supply voltages with external circuitry is described in Applications Information. Devices for operation at increased temperatures are available on special order. FEATURES AND BENEFITS s s s s s s s Fully Optimized Differential Digital Gear-Tooth Sensor Single-Chip Sensing IC for High Reliability Extremely Low Timing Accuracy Drift with Temperature Large Operating Air Gaps Small Mechanical Size Optimized Magnetic Circuit Patented Peak-Detecting Filter: <200 s Power-On Time <10 RPM Operation (single-tooth target) Correct First-Edge Detection Uses Small Value Ceramic Capacitors Under-Voltage Lockout Wide Operating Voltage Range Defined Power-Up State s s s Always order by complete part number, e.g., ATS610LSA . ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS ALLOWABLE PACKAGE POWER DISSIPATION IN mW Both sensors are packaged in miniature plastic housings that have been optimized for size, ease of assembly, and manufacturability. High operating temperature materials are used in all aspects of construction. Devices for operation at increased temperatures are also available on special order. ATS610LSA: Large-tooth, gear-position sensing -- crank angle, cam angle. ATS611LSB: Fine-pitch, large air gap, gear-speed sensing -- transmission, ABS. 1000 800 "SB" PACKAGE RJA ~ 150C/W "SA" PACKAGE RJA = 147C/W 600 400 200 0 20 40 60 100 140 80 120 AMBIENT TEMPERATURE IN C 160 180 Dwg. GH-065 FUNCTIONAL BLOCK DIAGRAM 1 SUPPLY REG UVLO POWER-ON LOGIC OUTPUT X MAGNET 2 E1 + - TRACK & HOLD 3 CAPACITOR + - 4 GROUND X E2 Dwg. FH-014 2 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 W Copyright (c) 2003 Allegro MicroSystems, Inc. ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS ELECTRICAL CHARACTERISTICS over operating voltage and temperature range, C3 = 0.1 F to 0.47 F. Limits Characteristic Supply Voltage Power-On State Under-Voltage Lockout Under-Voltage Hysteresis Output Saturation Voltage Output Leakage Current Supply Current Symbol VCC POS VCC(UV) VCC(hys) VOUT(SAT) IOFF ICC Test Conditions Operating, TJ < 165C VCC = 0 5 V IOUT = 20 mA, VCC = 0 5 V Lockout (VCC(UV)) - Shutdown IOUT = 20 mA VOUT = 16 V Output OFF Output ON Power-On Delay Output Rise Time Output Fall Time ton tr tf RL = 500 , CL = 10 pF RL = 500 , CL = 10 pF Min. VCC(UV) HIGH 2.5 - - - 5.5 8.5 - - - Typ. - HIGH - 0.1 90 0.2 7.7 10.5 - 0.2 0.2 Max. 16 HIGH 3.5 - 400 15 11 13 200 2.0 2.0 Units V - V V mV A mA mA s s s NOTE: Typical data is at VCC = 5 V and TA = +25C and is for design information only. www.allegromicro.com 3 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS ATS610LSA OPERATION over operating voltage and temperature range with reference target (unless otherwise specified). Limits Characteristic Air Gap Range Symbol AG Test Conditions Operating, Target Speed > 20 RPM Operating, One-Tooth (180) Target, Target Speed = 1000 RPM Operating, One-Tooth (180) Target, Target Speed = 1000 RPM Target Speed = 1000 RPM, 0.4 mm AG 2 mm Min. 0.4 Typ. - Max. 2.25 Units mm Minimum Air Gap AGmin - 0.25 - mm Maximum Air Gap AGmax - 2.75 - mm Timing Accuracy t - 0.5 1.0 ATS611LSB OPERATION over operating voltage and temperature range with reference target (unless otherwise specified). Limits Characteristic Air Gap Range Symbol AG Test Conditions Operating, Target Speed > 20 RPM Operating, One-Tooth (180) Target*, Target Speed = 1000 RPM Operating, One-Tooth (180) Target*, Target Speed = 1000 RPM Target Speed = 1000 RPM, 0.4 mm AG 2 mm Min. 0.4 Typ. - Max. 2.5 Units mm Minimum Air Gap AGmin - 0.75 - mm Maximum Air Gap AGmax - 3.25 - mm Timing Accuracy t - 0.5 1.0 * The one-tooth (180) target is not recommended for use with the ATS611LSB. 4 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS D o = 115 mm TARGET F (THICKNESS) 3 mm 3 m m T= 3m m h t= 5 E1 E2 AIR GAP SENSOR POLE PIECE SOUTH PERMANENT MAGNET NORTH 1 2 3 4 Dwg. MH-016 mm D o = 115 mm TARGET T = 180 (ONE TOOTH) F (THICKNESS) 3 mm ht =5 mm E1 E2 AIR GAP ONE-TOOTH (180) TARGET SENSOR POLE PIECE SOUTH PERMANENT MAGNET NORTH 1 2 3 4 Dwg. MH-016-1 mm www.allegromicro.com mm REFERENCE TARGET 5 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS TYPICAL ATS610LSA AND ATS611LSB ELECTRICAL CHARACTERISTICS 14 13 12 12 11 11 SUPPLY CURRENT IN mA OUTPUT ON 10 SUPPLY CURRENT IN mA OUTPUT ON 10 9.0 V =5V CC 9.0 8.0 8.0 OUTPUT OFF 7.0 OUTPUT OFF 7.0 T = 25C A 6.0 6.0 4.0 -40 5.0 0 40 80 120 160 200 2.0 6.0 10 14 18 AMBIENT TEMPERATURE IN C Dwg. GH-014-1 SUPPLY VOLTAGE IN VOLTS Dwg. GH-058 150 175 OUTPUT SATURATION VOLTAGE IN mV 150 125 I = 20 mA OUT OUTPUT SATURATION VOLTAGE IN mV 125 100 100 75 T A = 25C 50 75 25 50 -40 0 0 40 80 120 160 200 0 10 20 30 40 AMBIENT TEMPERATURE IN C Dwg. GH-013-1 OUTPUT SINK CURRENT IN mA Dwg. GH-059 6 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS TYPICAL ATS610LSA OPERATING CHARACTERISTICS (with reference target) 3.0 3.0 TRAILING TARGET EDGE LEADING TARGET EDGE 2.5 RELATIVE ACCURACY IN DEGREES 2.5 -40C +25C +150C 2.0 RELATIVE ACCURACY IN DEGREES -40C +25C +150C 2.0 1.5 1.5 1.0 1.0 0.5 0.5 0 0 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 Dwg. GH-008 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 AIR GAP IN MILLIMETERS AIR GAP IN MILLIMETERS Dwg. GH-008-2 53.0 52.8 52.6 -40C +25C +150C DUTY CYCLE IN PER CENT 52.4 52.2 52.0 51.8 51.6 51.4 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 Dwg. GH-008-1 AIR GAP IN MILLIMETERS continued next page... www.allegromicro.com 7 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS TYPICAL ATS610LSA OPERATING CHARACTERISTICS (with reference target) -- Continued 4.5 4.5 4.0 4.0 MAXIMUM AIR GAP IN MILLIMETERS 3.5 MAXIMUM AIR GAP IN MILLIMETERS 3.5 3.0 3.0 2.5 -40C +25C +150C 2.5 2.0 2.0 -40C +25C +150C 1.5 1.5 1.0 0 10 20 30 40 50 60 70 Dwg. GH-011-1 1.0 0 500 1000 1500 2000 2500 3000 3500 Dwg. GH-011 REFERENCE TARGET SPEED IN RPM REFERENCE TARGET SPEED IN RPM TYPICAL ATS611LSB OPERATING CHARACTERISTICS (with reference target) 4.5 4.0 MAXIMUM AIR GAP IN MILLIMETERS 3.5 3.0 2.5 2.0 -40C +25C +150C 1.5 1.0 0 500 1000 1500 2000 2500 3000 3500 REFERENCE TARGET SPEED IN RPM Dwg. GH-011-2 8 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS DEVICE DESCRIPTION The ATS610LSA and ATS611LSB dynamic, peak-detecting, differential Hall-effect gear-tooth sensors are Hall IC plus magnet modules that are fully optimized to provide digital detection of gear-tooth edges in a small package size. Both sensors are packaged in identical miniature plastic housings that have been optimized for size, ease of assembly, and manufacturability. High operating temperature materials are used in all aspects of construction. The application of these sensors is uncomplicated. After power is applied to the device, they are capable of quickly providing digital information that is representative of a rotating gear or specially designed target. No additional optimization or processing circuitry is required. This ease of use should reduce design time and incremental assembly costs for most applications. Sensing Technology. Both gear-tooth sensor modules contain a single-chip differential Hall-effect sensor IC, a samarium-cobalt magnet, and a flat ferrous pole piece. The Hall IC consists of two Hall elements spaced 2.235 mm (0.088") apart, which sense the magnetic gradient created by the passing of a ferrous object (a gear tooth). The two Hall voltages are compared and the difference is then processed to provide a digital output signal. The processing circuit uses a patented peak-detection technique to eliminate magnet and system offsets. This technique allows coupling and filtering of offsets without the power-up and settling time disadvantages of classical high-pass filtering schemes. Here, the peak signal of every tooth and valley is detected and is used to provide an instant reference for the operate-point and releasepoint comparators. In this manner, the thresholds are adapted and referenced to individual signal peaks and valleys, thereby providing immunity to zero-line variation due to installation inaccuracies (tilt, rotation, and off-center placement), as well as for variations caused by target and shaft eccentricities. The peak detection concept also allows extremely low-speed operation when used with small-value capacitors. OPERATE DIFFERENTIAL MAGNETIC FLUX OPERATE 0 RELEASE RELEASE V BB OUTPUT V OUT(SAT) Dwg. WH-011 Power-On Operation. The device will power on in the OFF state (output high) irrespective of the magnetic field condition. The power-on time of the circuit is no greater than 200 s. The circuit is then ready to accurately detect the first target edge that results in a HIGH-to-LOW transition. Under-Voltage Lockout. When the supply voltage is below the minimum operating voltage (VCC(UV)), the device is OFF and stays OFF irrespective of the state of the magnetic field. This prevents false signals, which may be caused by under-voltage conditions (especially during turn on), from appearing at the output. Output. The device output is an open-collector stage capable of sinking 25 mA. An external pull-up (resistor) to a supply voltage of not more than 18 V must be supplied. Superior Performance. The ATS610LSA and ATS611LSB peak-detecting differential gear-tooth sensors have several advantages over conventional Hall-effect gear-tooth sensors. continued next page... www.allegromicro.com 9 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS DEVICE DESCRIPTION -- Continued Differential vs. Single-Element Sensing. The differential Hall-element configuration is superior in most applications to the classical single-element gear-tooth sensor. The single-element configuration commonly used (Hall-effect sensor mounted on the face of a simple permanent magnet) requires the detection of a small signal (often <100 G) that is superimposed on a large back-biased field, often 1500 G to 3500 G. For most gear/target configurations, the back-biased field values change due to concentration effects, resulting in a varying baseline with air gap, with valley widths, with eccentricities, and with vibration. The differential configuration cancels the effects of the back-biased field and avoids many of the issues presented by the single Hall element. NOTE -- 10 G = 1 mT, exactly. Peak-Detecting vs. AC-Coupled Filters. High-pass filtering (normal ac coupling) is a commonly used technique for eliminating circuit offsets. AC coupling has errors at power up because the filter circuit needs to hold the circuit zero value even though the circuit may power up over a large signal. Such filter techniques can only perform properly after the filter has been allowed to settle, which is typically greater than one second. Also, highpass filter solutions cannot easily track rapidly changing baselines such as those caused by eccentricities. Peak detection switches on the change in slope of the signal and is baseline independent at power up and during running. Track-and-Hold Peak Detecting vs. Zero-Crossing Reference. The usual differential zero-crossing sensors are susceptible to false switching due to off-center and tilted installations, which result in a shift in baseline that changes with air gap. The track-and-hold peak-detection technique ignores baseline shifts versus air gaps and provides increased immunity to false switching. In addition, using track-and-hold peak-detecting techniques, increased air gap capabilities can be expected because a peak detector utilizes the entire peak-to-peak signal range as compared to zero-crossing detectors that switch on fixed thresholds. NOTE -- "Baseline" refers to the zero-gauss differential where each Hall-effect element is subject to the same magnetic field strength. TARGET SINGLE ELEMENT MAGNETIC FIELD IN GAUSS T -2000 DIFFERENTIAL MAGNETIC FIELD IN GAUSS A = 25C TARGET T A = 25C 1500 AIR GAP = 0.5 mm -2500 AIR GAP = 2.5 mm 1000 AIR GAP = 1.0 mm -3000 -3500 -4000 AIR GAP = 2.0 mm AIR GAP = 1.5 mm AIR GAP = 1.0 mm 500 0 -500 AIR GAP = 2.5 mm AIR GAP = 2.0 mm AIR GAP = 1.5 mm AIR GAP = 0.5 mm -4500 -5000 0 10 20 30 40 50 60 -1000 -1500 0 10 20 30 40 50 60 ANGLE OF TARGET ROTATION IN DEGREES Dwg. GH-061-1 ANGLE OF TARGET ROTATION IN DEGREES Dwg. GH-061 Single-element flux maps showing the impact of varying valley widths Differential flux maps vs. air gaps 10 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS APPLICATIONS INFORMATION Gear Diameter and Pitch. Signal frequency is a direct function of gear pitch and rotational speed (RPM). The width of the magnetic signal in degrees and, hence, the signal slope created by the tooth is directly proportional to the circumference of the gear (Do). Smaller diameters limit the low-speed operation due to the slower rate of change of the magnetic signal per degree of gear rotation (here the limitation is the droop of the capacitor versus the signal change). Larger diameters limit high-speed operation due to the higher rate of change of magnetic signal per degree of rotation (here the limitation is the maximum charge rate of the capacitor versus the rate of signal change). These devices are optimized for a 50 mm gear diameter (signal not limited by tooth width), 0.33 F capacitor, and speeds of 10 RPM to 8000 RPM. For very large diameter gears (diameter >200 mm), the devices must be configured with a lower value capacitor, but not less than 0.1 F. This allows for a range of 5:1 in gear diameters. NOTE -- In application, the terms "gear" and "target" are often interchanged. However, "gear" is preferred when motion is transferred. Air Gap and Tooth Geometry. Operating specifications are impacted by tooth width (T), valley width (pc - T) and depth (ht), gear material, and gear face thickness (F). The target can be a gear or a specially cut shaft-mounted tone wheel made of stamped ferrous metal. In general, the following gear or target guidelines must be followed to achieve greater than 2 mm air gap from the face of unit: Tooth width, T .............................. >2 mm Valley width, pc - T ...................... >2 mm (Whole) depth, ht ......................... >3 mm Gear material ............................... low-carbon steel Gear face width (thickness), F .... >3 mm Deviation from these guidelines will result in a reduction of air gap and a deterioration in timing accuracy. For applications that require the sensing of large-tooth targets, the optimal sensor choice is the ATS610LSA. Here, the higher switching thresholds provide increased immunity to false switching caused by magnetic overshoot and other non-uniformities in the gear or target. For applications that require the sensing of a target with a repetitive target structure (valley width less than 5 mm), the optimal sensor choice is the ATS611LSB. Here, the lower switching thresholds make the device more sensitive to magnetic field changes and will provide larger operating air gaps. Operation with Fine-Pitch Gears. For targets with a circular pitch of less than 4 mm, a performance improvement can be observed by rotating the front face of the sensor module. This sensor rotation decreases the effective sensor-to-sensor spacing and increases the capability of detecting fine tooth or valley configurations, provided that the Hall elements are not rotated beyond the width of the target. 2.235 2.235 COS TARGET FACE WIDTH, F >2.235 SIN A Signal Timing Accuracy. The magnetic field profile width is defined by the sensor element spacing and narrows in degrees as the target diameter increases. This results in improved timing accuracy performance for larger gear diameters (for the same number of gear teeth). The slope of this magnetic profile also changes with air gap, resulting in timing accuracy shift with air gap (refer to typical operating characteristic curves). Valley-to-tooth transitions will generally provide better accuracy than tooth-to-valley transitions for large-tooth or large-valley configurations. For highest accuracy, targets greater than 100 mm in diameter should be used. continued next page... A Dwg. MH-018-1 mm www.allegromicro.com 11 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS APPLICATIONS INFORMATION -- Continued Signal Duty Cycle. For repetitive target structures, precise duty cycle is maintained over the operating air gap and temperature range due to an extremely good symmetry in the magnetic switch points of the device. For nonrepetitive target structures, there will be a small but measureable change in pulse width versus air gap. Output Polarity. The output of the device will switch from HIGH to LOW as the leading edge of the target passes the module in the direction indicated below (pin 4 to pin 1), which means that the output will be LOW when the unit is facing a tooth. If rotation is in the opposite direction (pin 1 to pin 4), the output of the device will switch from LOW to HIGH as the leading edge of the target passes the module, which means that the output will be HIGH when the unit is facing a tooth. 1 2 3 4 4 3 2 1 Dwg. AH-007 Operation From a Regulated Power Supply. These devices require minimal protection circuitry during operation from a low-voltage regulated line. The on-chip voltage regulator provides immunity to power supply variations between 3.5 V and 16 V. However, even while operating from a regulated line, some supply and output filtering is required to provide immunity to coupled and injected noise on the supply line. A basic RC low-pass circuit (R1C1) on the supply line and an optional output capacitor (C2) is recommended for operation in noisy environments. Because the device has an open-collector output, an output pull-up resistor (RL) must be included either at the sensor output (pin 2) or by the signal processor input. SUPPLY RL OUTPUT C2 100 pF Dwg. AH-006-1 Power Supply Protection. The sensor contains an onchip voltage regulator and can operate over a wide supply voltage range. For devices that need to operate from an unregulated power supply, transient and double-battery protection should be added externally. For applications using a regulated supply, external EMI/RFI protection is often required. Insufficient protection can result in unexplained pulses on the output line, providing inaccurate sensing information to the user. The filter capacitor and EMI protection circuitry can easily be added to a PC board for use with these devices. Provisions have been made for simple mounting of a board on the back of the unit. 20 R1 C1 0.033 F 0.22 F C3 1 2 3 4 Vcc X X + - Dwg. EH-008-1A continued next page... 12 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS APPLICATIONS INFORMATION -- Continued Operation From an Unregulated Power Supply. In automotive applications, where the device receives its power from an unregulated supply such as the battery, full protection is generally required so that the device can withstand the many supply-side transients. Specifications for such transients vary between car manufacturers, and protection-circuit design should be optimized for each application. In the circuit below, a simple Zener-controlled regulator is constructed using discrete components. The RC low-pass filter on the supply line (R1C1) and a low-value supply bypass capacitor (CS) can be included, if necessary, so as to minimize susceptibility to EMI/RFI. The npn transistor should be chosen with sufficiently high forward breakdown voltage so as to withstand supply-side transients. The series diode should be chosen with sufficiently high reverse breakdown capabilities so as to withstand the most negative transient. The current-limiting resistor (RZ) and the Zener diode should be sized for power dissipation requirements. Capacitor Requirements. The choice of the capacitor at pin 3 (C3) defines the minimum operating speed of the target. This capacitor (0.1 F minimum) is required to stabilize the internal amplifiers as well as to eliminate the signal offsets. Typically, a 0.33 F low-leakage ceramic capacitor is recommended. Values greater than 0.47 F should not be used as this may cause high-speed performance degradation. Capacitor leakage current at pin 3 will cause degradation in the low-speed performance of the device. Excess capacitor leakage can result in the sensor changing output state without movement of the gear tooth being sensed. In addition to the capacitor leakage, it is extremely important to minimize the leakage at the PC board and between the pins of the sensor. Up to 50 nA of external leakage can be tolerated at the capacitor pin node to ground. Choice of low-leakage-current potting compounds and the use of clean PC board techniques are extremely important. SUPPLY RL OUTPUT C2 100 pF 2.5 k RZ 0.033 F CS 6.8 V 20 R1 C1 0.033 F 0.22 F C3 1 2 3 4 Vcc Additional applications Information on gear-tooth and other Hall-effect sensors is provided in the Allegro Electronic Data Book AMS-702 or Application Note 27701. X X + - Dwg. EH-008A www.allegromicro.com 13 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS MECHANICAL INFORMATION Component Sensor Face Plastic Housing Material Thermoset epoxy Thermoplastic PBT, 30% glass filled Function Maximum temperature 264 psi deflection temp. (DTUL) 66 psi deflection temp. (DTUL) Approximate melting temperature - - - - Units 170C* 204C 216C 225C - 8 oz. UL94V-0 Leads Lead Integrity Lead Finish Flame Class Rating Copper - 90/10 tin/lead solder plate - * Temperature excursions to 225C for 2 minutes or less are permitted. All industry-accepted soldering techniques are permitted for these modules provided the indicated maximum temperature for each component (e.g., sensor face, plastic housing) is not exceeded. Reasonable dwell times, which do not cause melting of the plastic housing, should be used. Sensor Location (in millimeters) (sensor location relative to package center is the design objective) Lead Cross-Section (in millimeters) 2.235 1.1 0.48 0.36 0.41 NOM. 0.1 0.44 0.35 0.38 NOM. A Dwg. MH-018 mm 0.0076 MIN. PLATING THICKNESS Dwg. MH-019A mm continued next page... 14 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS ATS610LSA DIMENSIONS IN MILLIMETERS 1.27 TYP 7.25 5.00 3 4 0.41 9.0 1 0.38 2 3.9 3.0 NOM 0.9 DIA A 8.3 8.0 SEE NOTE Dwg. MH-017A mm 2.0 9.0 ATS611LSB DIMENSIONS IN MILLIMETERS 1.27 TYP 8.8 7.0 3 4 0.41 7.0 1 0.38 2 3.9 3.0 NOM 0.9 DIA A 8.09 2.0 8.96 Dwg. MH-017-1B mm Tolerances unless otherwise specified: 1 place 0.1 mm, 2 places 0.05 mm. NOTE -- Nominal dimension and tolerances dependent on package material. Contact factory. www.allegromicro.com 15 ATS610LSA AND ATS611LSB DYNAMIC, PEAK-DETECTING, DIFFERENTIAL HALL-EFFECT GEAR-TOOTH SENSORS The products described herein are manufactured under one or more of the following U.S. patents: 5,045,920; 5,264,783; 5,442,283; 5,389,889; 5,581,179; 5,517,112; 5,619,137; 5,621,319; 5,650,719; 5,686,894; 5,694,038; 5,729,130; 5,917,320; and other patents pending. Allegro MicroSystems, Inc. reserves the right to make, from time to time, such departures from the detail specifications as may be required to permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that the information being relied upon is current. Allegro products are not authorized for use as critical components in life-support appliances, devices, or systems without express written approval. The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, Inc. assumes no responsibility for its use; nor for any infringements of patents or other rights of third parties that may result from its use. 16 115 Northeast Cutoff, Box 15036 Worcester, Massachusetts 01615-0036 (508) 853-5000 |
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