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The Working Principle of Sensor Resolvers
Sensor Resolvers are a type of electromagnetic sensor used to measure the angular position of a rotating element relative to a fixed reference. They operate on the principle of electromagnetic induction, utilizing the interaction between a rotating primary winding (or rotor) and a stationary secondary winding (or stator) to generate an output signal proportional to the angular position.
Rotor (Primary Winding): The rotating part of the resolver, which contains one or more coils of wire. As the rotor turns, it creates a changing magnetic field that interacts with the stator.
Stator (Secondary Winding): The stationary part of the resolver, containing one or more coils of wire arranged to intersect the magnetic field created by the rotor. The stator coils generate an output signal that varies with the angular position of the rotor.
Excitation: An AC excitation signal is applied to the rotor coils. This creates a rotating magnetic field within the resolver.
Electromagnetic Induction: As the rotor turns, the changing magnetic field induces an AC voltage in the stator coils. The amplitude and phase of this induced voltage depend on the angular position of the rotor relative to the stator.
Signal Processing: The output signal from the stator coils is typically a sinusoidal wave with an amplitude and phase that vary with the rotor's angular position. This signal is then processed by a resolver-to-digital converter (RDC) or similar device to determine the exact angular position of the rotor.
Absolute Positioning: Sensor Resolvers provide absolute position information, meaning they can determine the angular position of the rotor without the need for a reference point or home position.
High Accuracy: Sensor Resolvers offer high accuracy and precision in measuring angular position.
Ruggedness: They are designed to withstand harsh environments and can operate reliably in high temperatures, vibrations, and shocks.
Electromagnetic Immunity: Unlike some other sensors, Sensor Resolvers are immune to electromagnetic interference (EMI).
Longevity: Their contactless design eliminates wear and tear, resulting in long service life and low maintenance requirements.
Sensor Resolvers are widely used in various industrial and automotive applications, including:
Electric motor control
Servo systems
Robotics
Aerospace and defense
Heavy machinery
Process control systems
In summary, Sensor Resolvers work by utilizing the principle of electromagnetic induction to measure the angular position of a rotating element. Their high accuracy, ruggedness, and immunity to EMI make them an ideal choice for a wide range of industrial and automotive applications.
The Working Principle of Sensor Resolvers
Sensor Resolvers are a type of electromagnetic sensor used to measure the angular position of a rotating element relative to a fixed reference. They operate on the principle of electromagnetic induction, utilizing the interaction between a rotating primary winding (or rotor) and a stationary secondary winding (or stator) to generate an output signal proportional to the angular position.
Rotor (Primary Winding): The rotating part of the resolver, which contains one or more coils of wire. As the rotor turns, it creates a changing magnetic field that interacts with the stator.
Stator (Secondary Winding): The stationary part of the resolver, containing one or more coils of wire arranged to intersect the magnetic field created by the rotor. The stator coils generate an output signal that varies with the angular position of the rotor.
Excitation: An AC excitation signal is applied to the rotor coils. This creates a rotating magnetic field within the resolver.
Electromagnetic Induction: As the rotor turns, the changing magnetic field induces an AC voltage in the stator coils. The amplitude and phase of this induced voltage depend on the angular position of the rotor relative to the stator.
Signal Processing: The output signal from the stator coils is typically a sinusoidal wave with an amplitude and phase that vary with the rotor's angular position. This signal is then processed by a resolver-to-digital converter (RDC) or similar device to determine the exact angular position of the rotor.
Absolute Positioning: Sensor Resolvers provide absolute position information, meaning they can determine the angular position of the rotor without the need for a reference point or home position.
High Accuracy: Sensor Resolvers offer high accuracy and precision in measuring angular position.
Ruggedness: They are designed to withstand harsh environments and can operate reliably in high temperatures, vibrations, and shocks.
Electromagnetic Immunity: Unlike some other sensors, Sensor Resolvers are immune to electromagnetic interference (EMI).
Longevity: Their contactless design eliminates wear and tear, resulting in long service life and low maintenance requirements.
Sensor Resolvers are widely used in various industrial and automotive applications, including:
Electric motor control
Servo systems
Robotics
Aerospace and defense
Heavy machinery
Process control systems
In summary, Sensor Resolvers work by utilizing the principle of electromagnetic induction to measure the angular position of a rotating element. Their high accuracy, ruggedness, and immunity to EMI make them an ideal choice for a wide range of industrial and automotive applications.