MMA243F中文資料多維科技數(shù)據(jù)手冊PDF規(guī)格書
MMA243F規(guī)格書詳情
Features and Benefits
? Tunneling Magnetoresistance (TMR) Technology
? Large Output Signal Without Amplification
? Compatible with Wide Range of Supply Voltages
? High Resistance for Low Power Consumption
? Wide Airgap Tolerance
? Excellent Thermal Stability
? Very Low Hysteresis
? Ultrasmall Package
Applications
? Rotary Position Sensors
? Rotary Encoders
? Contactless Potentiometers
? Valve Position Sensors
? Knob Position Sensors
General Description
The output voltage of the MMA243F TMR angle sensor is proportional to the sine or cosine of the
angle of a magnetic field applied parallel to the surface of the sensor, which can be provided by a
small magnet positioned above the device. The MMA243F includes two Wheatstone bridges, which
can be configured to output sine and cosine functions respectively. Each bridge includes four TMR
sensor elements in a push-pull arrangement to produce a best-in-class peak-to-peak signal as large
as 80% of the supply voltage, eliminating the need for amplification in many applications.
Additionally, the unique TMR Wheatstone bridge technology accurately compensates the output
against changes in ambient temperature. This sensor is assembled in an ultra small LGA8 package
of 3.0 mm ? 3.0 mm ? 0.75 mm.
Operation
A small magnet, placed above the MMA243F, can be used to provide a magnetic field in any
desired orientation parallel to the plane of the MMA243F package. The magnetic field is detected
by TMR sensors in the MMA243F that are composed of two magnetic layers. One layer of the
TMR sensors is a “pinned layer” that is not affected by the magnetic field, and the other is “free
layer,” which has a magnetization that aligns parallel to the applied magnetic field. Because the
TMR effect produces a resistance that is proportional to the sine or cosine of the relative difference
between the free and pinned layer magnetization orientations, the sensor output voltage is
sinusoidally dependent on the angle of the applied magnetic field, thereby providing a measure of
the orientation of the magnet.