Hall sensors
2Dex™ Hall Sensor Technology Features
- Sensor technology used in FP Series probes for the F71/F41 teslameters
- Under development for release as stand-alone sensors for higher volume applications
- Plug-and-play versions are now available for direct connection to F71/F41 teslameters
- Improved sensor ruggedness
- Active area indicators where possible
2Dex™ Hall Sensor Technology Features
- Sensor technology used in FP Series probes for the F71/F41 teslameters
- Under development for release as stand-alone sensors for higher volume applications
- Plug-and-play versions are now available for direct connection to F71/F41 teslameters
- Improved sensor ruggedness
- Active area indicators where possible
2Dex™ Plug-and-Play Hall Sensor Features
- Selectable teslameter cable length
- Integrated thermistor for temperature compensation
- Sensor calibration data stored on the connector
- Small active area
- Connects directly to a teslameter for high accuracy measurement
InAs and GaAs Hall Sensor Features
- Multiple packages available
- Options for high stability or sensitivity
- Compatible with Lake Shore 400 Series gaussmeters
Hall effect sensors provide a convenient method for measuring or detecting magnetic fields electronically by providing an output voltage proportional to magnetic flux density. As implied by its name, this device relies on the Hall effect. The Hall effect is the development of a voltage across a sheet of conductor when current is flowing and the conductor is placed in a magnetic field.
Lake Shore offers a range of Hall sensors aimed at various applications. In all cases, these sensors go beyond the application of simple magnetic presence detection such as those used in encoders, contactless switches, and electronic compasses. Lake Shore sensors are useful for field measurement applications, where field value, direction, and polarity are of interest.
Simplify your field measurements
- Connect sensor directly to a Lake Shore teslameter and read field values directly
- Superior accuracy with full calibration, temperature, and linearity compensation
Hall sensor selection guide
Lake Shore Hall sensors offer the flexibility to power and read the resulting hall voltage with your own instrumentation.
| 2Dex IN DEVELOPMENT | InAs—stable | InAs—sensitive | GaAs | |
| What makes this work? Words to impress your boss | Thin-film technology using a 2‑dimensional electron gas (2DEG) structure | Indium arsenide bulk material, doped for high stability | Indium arsenide bulk material, doped for high sensitivity | Gallium arsenide thin film |
| Temperature range An advantage of non-silicon-based Hall sensors is the opportunity for use in more extreme temperatures | 1 K to 402 K (-272 °C to 125 °C) | 1.5 K to 375 K (-271.5 °C to 102 °C) | 208 K to 373 K (-65 °C to 100 °C) | 233 K to 402 K (-40 °C to 125 °C) |
| Interchangeability Ability to operate multiple sensors with identical drive and measurement setups | Good—narrow range of sensitivity values, excellent linearity, and small offset voltage | Poor—sensitivity range is large enough to require knowledge of the average sensitivity value | Poor—sensitivity range is large enough to require knowledge of the average sensitivity value | Poor—sensitivity range is large enough to require knowledge of the average sensitivity value |
| Ruggedness Ability to survive shock and vibration | Good | Poor | Poor | Good |
| Lake Shore instrument compatibility Gaussmeter/teslameter compatibility for these sensors, allowing for field values to automatically be displayed by the instrument | F71 or F41 teslameter with plug-and-play sensors—full sensor calibration and temperature compensation providing accuracy equivalent to a full teslameter probe | 425 or 475 gaussmeter using HMCBL cable; field conversion accomplished with single sensitivity value only, meaning linearity and temperature compensation is not carried out by the gaussmeter | 425 or 475 gaussmeter using HMCBL cable; field conversion accomplished with single sensitivity value only, meaning linearity and temperature compensation is not carried out by the gaussmeter | None |
| Planar Hall effect Physical property related to Hall element thickness that introduces measurement error when the field is in-plane with the sensor element | None, making these sensors ideal for measuring fields with unknown orientation | Significant—bulk material produces enough of a planar Hall effect that fields with known directions are required for accurate measurements | Significant—bulk material produces enough of a planar Hall effect that fields with known directions are required for accurate measurements | Some—thin film elements may exhibit small amounts of planar Hall effect error |
| Sensitivity at nominal current Impacts measurement accuracy and resolution—a higher number is better | 50 to 53 mV/T anticipated | 5.5 to 11 mV/T | 55 to 125 mV/T | 110 to 280 mV/T |
| Sensitivity temperature coefficient Impacts accuracy during large temperature shifts | 200 ppm/°C anticipated | 50 ppm/°C | 800 ppm/°C | 600 ppm/°C |
| Nominal drive current The recommended excitation level for these sensors | 1 mA | 100 mA | 100 mA | 1 mA |
| Typical input resistance Useful when selecting the drive circuit | 800 Ω | 2 Ω | 2 Ω | 750 Ω |
| Typical input resistance temperature coefficient An additional source of measurement error if using a voltage source (rather than current source) to power the sensor | 0.7%/°C anticipated | 0.15%/°C | 0.18%/°C | 0.2%/°C |
| Best offset voltage (field equivalent) An error component that has a bigger impact at small fields | To be determined | ±50 µV (4.5 mT) | ±75 µV (0.6 mT) | ±2.8 mV (10 mT) |