AH3503 Linear Hall Effect Sensor – TO-92, 3.5V–6.6V

AH3503 Linear Hall Effect Sensor – TO-92, 3.5V–6.6V

$0.79 NZD
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AH3503 Linear Hall Effect Sensor – TO-92, 3.5V–6.6V

$0.79 NZD
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The AH3503 is a ratiometric linear Hall effect sensor in a TO-92 package. It outputs a continuous analog voltage proportional to magnetic field strength -- rising above the midpoint for a north pole and falling below for a south pole. Works directly with Arduino, ESP32, and Raspberry Pi (with an external ADC).

  • Linear analog output -- continuous voltage, not a switch
  • Ratiometric: output scales with supply voltage
  • Bipolar -- detects north and south poles
  • Supply voltage 3.5V-6.6V (3.3V and 5V systems)
  • Sensitivity 15.25 mV/mT typical at 5V
  • Linear range ±80 mT
  • Output range 0.1V-4.9V at 5V supply
  • Zero-field output ~2.5V at 5V (VCC / 2)
  • TO-92A package, 3-pin, 1.27 mm lead pitch
  • Operating temp -40°C to +85°C

Specifications

Model AH3503
Output type Linear analog (ratiometric)
Supply voltage 3.5V-6.6V DC
Output voltage 0.1V-4.9V (at 5V supply)
Zero-field output ~2.5V at 5V supply (VCC / 2)
Sensitivity 15.25 mV/mT typical at 5V
Linear range ±80 mT (bipolar)
Package TO-92A, 3-pin, 1.27 mm lead pitch
Sensing face Flat (printed) face of TO-92 body
Operating temp -40°C to +85°C
MCU compatibility Arduino, ESP32, Raspberry Pi (via ADC)

Wiring & getting started

  1. Hold the sensor with the flat printed face toward you, legs pointing down. Pins 1, 2, 3 run left to right.
  2. Pin 1 -- VCC: 5V for Arduino Uno; 3.3V for ESP32 or Raspberry Pi.
  3. Pin 2 -- GND: common ground of your circuit.
  4. Pin 3 -- analog in (A0): read with analogRead(A0). Returns 0-1023 on a 5V Arduino.
  5. Calibrate zero field: no magnet present reads around 512. Above 512 = north pole; below 512 = south pole.

Great for

RPM and speed sensing

Count magnet passes per revolution for accurate motor, fan, or wheel speed measurement.

E-bike and scooter throttle

Smooth linear throttle control for electric vehicle drive systems and speed controllers.

BLDC motor commutation

Detect rotor position in brushless DC motors for precise electronic commutation timing.

Linear and rotary position

Non-contact position sensing with a sliding or rotating magnet -- no wear, no contact.

Robotics feedback

Joint angle sensing, gripper position detection, and servo arm control in robotics builds.

Arduino projects

Direct analog read on Arduino A0 -- no extra components or op-amp needed.

FAQ

Is the AH3503 a digital or analog Hall sensor?
The AH3503 is a linear analog sensor -- it outputs a continuous voltage proportional to field strength, not a simple HIGH/LOW switch. For on/off detection use a Hall switch such as the A3144.
Will it work with an Arduino Uno at 5V?
Yes. Pin 1 to 5V, Pin 2 to GND, Pin 3 to A0. Use analogRead(A0) to read 0-1023. Around 512 = no field; above 512 = north pole; below 512 = south pole.
Can I use this with an ESP32 or Raspberry Pi?
Yes. Supply at 3.3V for ESP32 and connect OUT to any ADC pin (zero-field output approx. 1.65V). Raspberry Pi needs an external ADC such as the MCP3008 -- it has no built-in analog inputs.
What output voltage with no magnet present?
Approximately half the supply voltage -- about 2.5V at 5V, about 1.65V at 3.3V. This midpoint is ratiometric and tracks VCC proportionally.
Which face of the TO-92 is the sensing side?
The flat printed face (labelled "503 118") is the active sensing side. Point this face directly at your magnet for maximum sensitivity.
Does it detect both north and south magnetic poles?
Yes. The ±80 mT range is fully bipolar -- north raises the output above midpoint, south lowers it below. Ideal for absolute angle sensing with a diametrically-magnetised magnet.

Good to know: For higher precision, add a 100 nF decoupling capacitor between VCC and GND close to the sensor pins. On ESP32, always calibrate at your actual 3.3V supply -- the ratiometric output shifts with voltage.

Why buy from NZN

International prices. None of the international wait.

We're a small Kiwi-owned shop, and we stock the same boards and parts you'd usually order from overseas, for about the same price. The only real difference is they ship from Te Awamutu, so you get them in a few days instead of waiting weeks.

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Order before 8am and it ships the same day, otherwise within 24 hours guaranteed. No waiting three to six weeks for a parcel to crawl over from overseas.

Low prices are the goal

As a maker myself, I want New Zealand to have a genuine low-price local option for electronics, not overpriced shelves or a long wait on an international parcel.

Checked, and easy to sort if it's not right

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Packed and sent by a fellow maker, right here in Te Awamutu.

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