A speed estimation apparatus for an AC motor includes a model deviation calculation unit, first and second angular velocity estimation units, and an adder. The deviation calculation unit calculates a model deviation based on a voltage, a current, and an estimated angular velocity of the motor. The first angular velocity estimation unit calculates a first estimated angular velocity as a low-frequency component including a DC component of a real angular velocity based on the model deviation. The second angular velocity estimation unit calculates a second estimated angular velocity as a high-frequency component of a real angular velocity based on a specific high-frequency component of the model deviation. The adder adds the first and second estimated angular velocities together. An addition value of the first and second estimated angular velocities is fed back as the estimated angular velocity to the deviation calculation unit.

A speed estimation apparatus for an AC motor includes a model deviation calculation unit, first and second angular velocity estimation units, and an adder. The deviation calculation unit calculates a model deviation based on a voltage, a current, and an estimated angular velocity of the motor. The first angular velocity estimation unit calculates a first estimated angular velocity as a low-frequency component including a DC component of a real angular velocity based on the model deviation. The second angular velocity estimation unit calculates a second estimated angular velocity as a high-frequency component of a real angular velocity based on a specific high-frequency component of the model deviation. The adder adds the first and second estimated angular velocities together. An addition value of the first and second estimated angular velocities is fed back as the estimated angular velocity to the deviation calculation unit.

The present disclosure relates to a pressure transducer comprising a process module having a cylindrical main part made of a first material. A pressure-sensitive process diaphragm and an axially disposed through-hole are provided in the main part. The pressure transducer includes a measuring module having a cylindrical base which is manufactured from a second material that differs from the first material. The base has a pressure sensor and a pin-like portion, where the pin-like portion projects into the through-hole such that an end portion of the pin-like portion is flush with the end portion of the main part facing the medium. The end portion of the pin-like portion is connected to the end portion of the main part facing the medium, where the pin-like portion tapers in the direction of the end portion of the pin-like portion.

The present disclosure relates to a pressure transducer comprising a process module having a cylindrical main part made of a first material. A pressure-sensitive process diaphragm and an axially disposed through-hole are provided in the main part. The pressure transducer includes a measuring module having a cylindrical base which is manufactured from a second material that differs from the first material. The base has a pressure sensor and a pin-like portion, where the pin-like portion projects into the through-hole such that an end portion of the pin-like portion is flush with the end portion of the main part facing the medium. The end portion of the pin-like portion is connected to the end portion of the main part facing the medium, where the pin-like portion tapers in the direction of the end portion of the pin-like portion.

A method for rapidly optimizing an antiregulation effect of a power system stabilizer includes: Step 1, deriving specific parameters influencing the antiregulation effect of the power system stabilizer; Step 2, dividing the specific parameters influencing the antiregulation effect of the power system stabilizer into a fixed part and a regulable part; and Step3, performing a step of a voltage at a generator end for the regulable part influencing the antiregulation effect of the power system stabilizer, determining whether a numerical value of a set node after the step falls within a set range, further determining whether antiregulation exists in two channels of rotational speed w and power p of the power system stabilizer, regulating, in a case that the antiregulation exists, the regulable part, causing the numerical value of the set node to fall within the set range, and causing the antiregulation to disappear.

A method for rapidly optimizing an antiregulation effect of a power system stabilizer includes: Step 1, deriving specific parameters influencing the antiregulation effect of the power system stabilizer; Step 2, dividing the specific parameters influencing the antiregulation effect of the power system stabilizer into a fixed part and a regulable part; and Step3, performing a step of a voltage at a generator end for the regulable part influencing the antiregulation effect of the power system stabilizer, determining whether a numerical value of a set node after the step falls within a set range, further determining whether antiregulation exists in two channels of rotational speed w and power p of the power system stabilizer, regulating, in a case that the antiregulation exists, the regulable part, causing the numerical value of the set node to fall within the set range, and causing the antiregulation to disappear.