KR20170017837A - A magnetic sensor and an integrated circuit - Google Patents

Abstract

The present invention relates to a magnetic sensor including an input port connected to an external power source, a magnetic field sensing circuit configured to generate a magnet sensing signal, an output control circuit configured to control an operation of the magnetic sensor in response to the magnet sensing signal, and an output port. The magnetic field sensing circuit includes a magnetic sensing element configured to sense an external magnetic field and output a sensing signal, a signal processing element configured to amplify the sensing signal and removing interference from the sensing signal for a processed sensing signal to be generated, and an analog-digital conversion element configured to convert the processed sensing signal to the magnet sensing signal. An output control signal is configured to control the magnetic sensor so that at least one of a first state and a second state is put into operation in response to one or more magnet sensing signals.

Description

[0001] MAGNETIC SENSOR AND AN INTEGRATED CIRCUIT [0002]

This disclosure relates to the field of circuit technology. Specifically, this disclosure relates to magnetic sensors. The disclosure also relates to a driver for a permanent magnetic motor.

Magnetic sensors are widely used in modern industrial and electronic products to sense magnetic field strength and to measure physical parameters such as current, position and direction. Motors are an important application of magnetic sensors. The magnetic sensor can serve as a rotor excitation position sensor in the motor.

In the conventional technique, the magnetic sensor can generally output only the magnetic field detection signal. However, since the magnetic field detection signal is weak and mixed with the offset of the magnetic sensor, it is difficult to obtain an accurate magnetic field gradient signal.

The present disclosure provides magnetic sensors and their applications. According to one embodiment of the present disclosure, a magnetic sensor comprises: an input port connected to an external power source; A magnetic field detection circuit configured to generate a magnetic detection signal; An output control circuit configured to control an operation of the magnetic sensor in response to the magnetic detection signal; And an output port, the magnetic field detection circuit comprising: a magnetic sensing element configured to detect an external magnetic field and output a detection signal; a signal configured to amplify the detection signal and remove interference from the detection signal to produce a processed detection signal; A conversion element configured to convert the processed signal and the processed detection signal into a magnetic detection signal, the conversion element being used to control the magnetic sensor to operate in at least one of a first state and a second state responsive to at least a magnetic detection signal - in the first state, the load current flows from the output port of the magnetic sensor to the outside, and in the second state, the load current flows from the outside of the magnetic sensor into the output port.

In a specific embodiment, the detection signal comprises a magnetic field signal and a deviation signal, the signal processing element comprises a first chopper switch configured to separate the detection signal into a deviation signal and a magnetic field signal corresponding respectively to a chopper frequency and a baseband frequency, A chopper amplifier configured to amplify the signal and magnetic field signals and to switch the amplified deviation signal and the amplified magnetic field signal to chopper frequency and baseband frequency respectively and a filter circuit configured to filter out the deviation signal at chopper frequency .

In a particular embodiment, the chopper amplifier comprises a first amplifier and a second chopper switch, wherein the first amplifier receives a deviation signal from the first chopper switch and a magnetic field signal from the first chopper switch to produce an amplified deviation signal and an amplified magnetic field signal, Stage amplification, and the second chopper switch is configured to switch the amplified deviation signal and the amplified magnetic field signal to the chopper frequency and the baseband frequency, respectively.

In a particular embodiment, the first amplifier comprises a folding cascade amplifier.

In a particular embodiment, the chopper amplifier further comprises a second amplifier connected in series to the second chopper switch, the second amplifier having an amplified deviation signal switched to the chopper frequency and an amplified magnetic field signal switched to the baseband frequency Stage amplification.

In a particular embodiment, the signal processing element further comprises sample and hold circuitry coupled between the chopper amplifier and the filter circuit, wherein the sample and hold circuitry is operable to couple the first pair of differential signals during the first clock half- And to output two pairs of sampled differential signals during the clock period.

In a particular embodiment, the filter circuit further comprises a first filter configured to compute a second pair of differential signals based on two pairs of sampled differential signals.

In a particular embodiment, the filter circuit further comprises a second filter configured to further amplify the second pair of differential signals, remove the deviation signal and generate a third pair of differential signals.

In a particular embodiment, the transducer comprises a first comparator configured to compare an output voltage determined based on a third pair of high-voltage thresholds and the differential signal; A second comparator configured to compare the output voltage with a low voltage threshold; And outputting a first voltage when the output voltage is higher than the high voltage threshold or a second voltage when the output voltage is lower than the low voltage threshold or the output voltage is lower than the low voltage threshold and the high voltage A latch logic circuit configured to maintain an output of the transducer element when it is between a threshold and a high voltage threshold and a low voltage threshold determined based on a differential voltage reference pair, The comparator and the second comparator take as inputs a first pair of differential signals and a pair of differential voltage references from the filter circuit.

In certain embodiments, the latch logic circuit outputs a second voltage when the first voltage or field strength does not reach a preset release point when the magnetic field strength reaches a predetermined operating point, or the second voltage when the magnetic field strength reaches a predetermined release point And the output of the converting element when it is between the predetermined operating point.

In a particular embodiment, the magnetic sensor comprises a rectifier circuit coupled to the input port and configured to provide a voltage supply to the magnetic field detection circuit, and a control circuit for controlling the magnetic sensor to operate in at least one of the first state and the second state based on the magnetic detection signal. Wherein the output control circuit includes a first switch coupled to the output port to form a first current path that allows the load current to flow from the output port to the outside of the magnetic sensor in a first state, And a second switch coupled to the output port to form a second current path that allows the load current to flow from the outside of the magnetic sensor to the output port in a second state, Lt; RTI ID = 0.0 > 2 < / RTI > current paths.

In a particular embodiment, the first switch is a diode and the second switch is a diode or transistor.

In another embodiment of the present disclosure, an integrated circuit for a magnetic sensor comprises: an input port connected to an external power source; Output port; And a magnetic field detection circuit configured to generate a magnetic detection signal, wherein the magnetic field detection circuit is configured to detect an external magnetic field and output a detection signal, the detection signal including a magnetic field signal and a deviation signal, A signal processing element configured to amplify a detection signal and to remove interference to produce a processed detection signal, and a signal processing element configured to detect the processed magnetic detection signal in at least one of a first state and a second state responsive to at least the magnetic detection signal. To a magnetic detection signal used to control the chopper frequency and the baseband frequency to operate, and the signal processing element comprises: a means for separating the detection signal into the deviation signal and the magnetic field signal, The first chopper switch, the deviation signal and the magnetic field signal are separately amplified A filter circuit configured to remove the deviation signal and the switching of the amplified error signal and the amplified magnetic field signal to each of the chopper frequency and a chopper amplifier and a chopper frequency which is configured to switch to the base band frequency.

In another embodiment of the present disclosure, the motor assembly comprises: a motor coupled with an external power source for providing alternating current (AC) power to the motor; A magnetic sensor configured to detect a magnetic field generated by the motor; And a bi-directional switch configured to control the motor based on the operating state of the magnetic sensor determined based on the detected magnetic field, wherein the magnetic sensor is configured to detect the magnetic field and generate a magnetic detection signal based on the detected magnetic field And an output control circuit configured to control the magnetic sensor to operate in at least one of a first state and a second state responsive to at least a magnetic detection signal based on the magnetic field detection circuit and the magnetic detection signal, , The current flows from the outside of the magnetic sensor to the inside of the magnetic sensor, and in the second state, the current flows from the magnetic sensor to the outside of the magnetic sensor.

The methods, systems, and / or programming described herein are further described in terms of exemplary embodiments. These embodiments are described in detail with reference to the drawings. These embodiments are non-limiting examples in which reference numerals indicate like structures throughout the drawings.
1 is an exemplary schematic diagram of a magnetic sensor in accordance with an embodiment of the present disclosure;
2 is an exemplary schematic diagram of the signal processing element 1110 according to an embodiment of the present disclosure.
3A is an exemplary schematic diagram of a chopper amplifier 1204 in accordance with one embodiment of the present disclosure.
3B is another schematic diagram of a chopper amplifier 1204 in accordance with one embodiment of the present disclosure.
4 is an exemplary schematic diagram of a magnetic sensor in accordance with one embodiment of the present disclosure;
5 is an exemplary schematic diagram of a rectifier circuit 1402 according to one embodiment of the present disclosure.
6 is an exemplary circuit diagram of a Hall detector 1420 and a first chopper switch in accordance with one embodiment of the present disclosure.
FIG. 7 illustrates an exemplary signal output according to the circuit diagram of FIG.
8 is an exemplary circuit diagram of a filter circuit 1428 according to one embodiment of the present disclosure.
9 is an exemplary circuit diagram of a comparator circuit 1430 according to one embodiment of the present disclosure.
10 is an exemplary schematic diagram for determining the polarity of the magnetic field.
Figure 11 shows an exemplary signal output of a clock period.
12 is an exemplary circuit diagram of an output control circuit 1406 according to one embodiment of the present disclosure.
13 is an exemplary circuit diagram of an output control circuit according to another embodiment of the present disclosure;
14 is an exemplary circuit diagram of an output control circuit according to another embodiment of the present disclosure;
15 is an exemplary schematic diagram of a motor 2500 incorporating a magnetic sensor constructed in accordance with the present disclosure.
16 is an exemplary schematic diagram of a synchronous motor 2600 incorporating a magnetic sensor constructed in accordance with the present disclosure.

In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the related art. However, it will be apparent to those skilled in the art that the present invention may be practiced without such details. In other instances, well-known methods, procedures, systems, components, and / or circuits have been described at a relatively high level without detail in order to avoid unnecessarily obscuring aspects of the present invention.

Throughout the description and the claims, a term may have subtle meaning suggested or implied in terms that is beyond the explicitly stated meaning. Similarly, the term " in one embodiment / example "used herein need not necessarily refer to the same embodiment, and the term " in another embodiment / example" For example, the claimed subject matter is intended to include a combination of exemplary embodiments in whole or in part.

In general, terms may be at least partially understood from contextual use. For example, terms such as "and" or "or" and / or ", as used herein, may include various meanings that may depend on at least a part of the context in which such term is used. In general, when "or" is used to relate a list such as A, B, or C used herein, A, B, or C, which are used exclusively, in addition to A, C, respectively. Furthermore, the term "one or more ", as used herein, is to be interpreted as referring to any characteristic, structure, or characteristic in a single sense, or to describe a combination of characteristic, . Similarly, terms such as "a "," an ", or "the" may again be understood to convey singular or at least multiple uses depending at least in part on the context. It should also be understood that the term "based on" is not intended to convey an exclusive set of factors, but instead permits the presence of additional factors that are not necessarily undifferentiated again, can do.

The disclosed magnetic sensor uses at least one folded cascade amplifier. A folded cascade amplifier can efficiently amplify a very small input signal to have a large gain. In addition, folded cascade amplifiers are configured with excellent frequency characteristics and are capable of processing signals that extend over a very wide frequency range. In addition, the disclosed magnetic sensor can be directly connected to a city AC power source without requiring additional A / D conversion equipment. Therefore, the present disclosure facilitates the implementation of magnetic sensors in various fields. In addition, the magnetic field detection circuit can efficiently filter the interference signal by amplifying the detected magnetic field signal and adjusting the voltage. Therefore, the magnetic sensor can generate a more accurate signal about the polarity of the external magnetic field to control the operation of the electric rotor.

Additional novel features will be set forth in part in the description that follows, and in part will be apparent to those skilled in the art upon examination of the following description and accompanying drawings, and may be learned by way of example production or operation. The novel features of the present disclosure may be realized and obtained by means of the practice or use of the various aspects of the methods, means and combinations described above in the detailed examples discussed below. A magnetic sensor, a signal processing method performed in a magnetic sensor, and a motor using a magnetic sensor, and a signal processing method disclosed herein are known to any one of ordinary skill in the art and include any circuitry not limited to integrated circuits and other circuit implementations Technology. ≪ / RTI >

1 is an exemplary schematic diagram of a magnetic sensor according to an embodiment of the present disclosure; The magnetic sensor according to the present embodiment includes an input port 1102, a magnetic field detection circuit 1104, and an output port 1106. The input port 1102 is coupled to an external power source and is configured to provide power to the magnetic field detection circuit 1104. In a particular embodiment, the external power source is a direct current (DC) power source. In another embodiment, the external power source is an alternating current (AC) power source. The magnetic field detection circuit 1104 is configured to detect an external magnetic field to generate a magnetic field detection signal. The magnetic field detection signal 1106 is applied to control the operating state of the magnetic sensor and any electric equipment using the motor or magnetic sensor.

The magnetic field detection circuit 1104 may include a magnetic sensing element 1108, a signal processing element 1110, and a conversion element 1114. The magnetic sensing element 1108 is configured to sense an external magnetic field and output a first detection signal 1120. The first detection signal 1120 output from the magnetic sensing element 1108 includes at least a magnetic field signal and a deviation signal. The magnetic field signal represents the actual magnetic voltage signal associated with the external magnetic field sensed by the magnetic sensing element 1108. [ The deviation signal is a bias signal unique to the magnetic sensing element 1108.

The signal processing element 1110 amplifies the received first detection signal 1120 and removes the interference signal from the first detection signal 1120 because the actual magnetic voltage signal may be interfered at least by the inherent bias signal To generate a second detection signal 1122. [ In a particular embodiment, the signal processing element 1110 may include at least one folded cascade amplifier 1112.

The conversion element 1114 is configured to convert the second detection signal 1122 into a magnetic field detection signal and output a magnetic field detection signal through the output port 1106. [ In a particular embodiment, the magnetic field detection signal is a switching detection signal.

FIG. 2 illustrates an exemplary schematic diagram of a signal processing element 1110 according to an embodiment of the present disclosure. The signal processing element 1110 according to FIG. 1 includes a first chopper switch (Z1) 1202 and a first chopper amplifier (IA) 1204. The first chopper switch 1202 is configured to separate the deviation signal and the magnetic field signal carried separately on the baseband frequency and the chopper frequency. The first chopper amplifier 1204 is configured to amplify the deviation signal and the magnetic field signal and to switch the amplified deviation signal and the magnetic field signal to the chopper frequency and the baseband frequency, respectively, for transmission. In a particular embodiment, the chopper frequency is a baseband frequency larger than 100K Hz is less than 200 Hz.

In a particular embodiment, when the external power source is an AC power source, the baseband frequency is proportional to the frequency of the AC power source. In certain embodiments, the baseband frequency is twice the frequency of the AC power source.

In a particular embodiment, the signal processing element 1110 may further include a low pass filter (LPF) 1206 configured to remove the deviation signal transmitted over the chopper frequency.

In this embodiment, each of the inputs and outputs of the first chopper switch (Z1) 1202, the first chopper amplifier (IA) 1204 and the low-pass filter (LPF) 1206 is shown as a single line. It should be understood that FIG. 2 is for illustrative purposes. The disclosure is not intended to be limiting. The inputs and outputs of the first chopper switch (Z1) 1202, the first chopper amplifier (IA) 1204 and the low pass filter (LPF) 1206 may be one or more input / output signals. In a particular embodiment, each of the inputs / outputs of a first chopper switch (Z1) 1202, a first chopper amplifier (IA) 1204 and a low-pass filter (LPF) 1206 includes one or more pairs of differential signals .

3A shows an exemplary schematic diagram of a chopper amplifier 1204 in accordance with an embodiment of the present disclosure. The first chopper amplifier (IA) 1204 of FIG. 2 includes a first amplifier (A1) 1302 and a second chopper switch (Z2) 1304. The first amplifier (A1) 1302 is configured to perform a first stage amplification of the deviation signal and the magnetic field signal from the first chopper switch (Z1) 1202. In a particular embodiment, the first amplifier (A1) 1302 is implemented using at least one folded cascade amplifier, such as 1112. The second chopper switch (Z2) 1304 is configured to switch the amplified deviation signal and magnetic field signal for transmission to the chopper frequency and the baseband frequency, respectively.

3B illustrates an exemplary schematic diagram of a chopper amplifier 1204 in accordance with another embodiment of the present disclosure. In the illustrated embodiment, the first chopper amplifier (IA) 1204 of FIG. 2 includes a second amplifier A2 (in addition to the first amplifier A1) 1302 and the second chopper switch Z2 1304 1306). The second amplifier (A2) 1306 is configured to further perform the second stage amplification of the magnetic field signal and the deviation signal from the second chopper switch (Z2) 1304. In a particular embodiment, the second chopper switch (Z2) 1304 is implemented based on a single-stage amplifier.

It should be understood that the connection of the first amplifier A1, 1302, the second chopper switch Z2 1304 and the second amplifier A2 1306 of Figure 3B is for illustrative purposes. The disclosure is not intended to be limiting. In a particular embodiment, a second amplifier (A2) 1306 may be disposed between the first amplifier (A1) 1302 and the second chopper switch (Z2) 1304.

Figure 4 shows an exemplary schematic diagram of a magnetic sensor according to another embodiment of the present disclosure. The magnetic sensor according to the present disclosure includes an input port 1408, a rectifier circuit 1402, a magnetic field detection circuit 1404, an output control circuit 1406, and an output port 1410. The input port 1408 of this embodiment includes a pair of input ports 1408A and 1408B coupled to an external power source. In certain embodiments, the input port 1408 may be coupled in series to an external power source. In another embodiment, the input port 1408 may be connected in parallel to an external power source.

The rectifier circuit 1402 may be implemented based on a full-wave rectifier bridge and a voltage regulator (not shown). The full wave rectifier bridge may be configured to convert an AC signal from an AC power source to a DC signal. The voltage regulator may be configured to regulate a DC signal within a preset range. The rectifier circuit 1402 supplies the regulated DC signal to the magnetic field detection circuit 1404 and the output control circuit 1406.

In the illustrated embodiment, the magnetic field detection circuit 1404 includes a Hall detector 1420, a first chopper switch 1422, a first chopper amplifier 1424, a sample and hold circuit 1426, a filter circuit 1428, And a comparator circuit 1430. Hall detector 1420 detects the magnetic field signal and is coupled to rectifier circuit 1402 to output the detected magnetic field signal to first chopper switch 1422. The first chopper switch 1422 is configured to perform the same function as the first chopper switch 1202 shown in FIG. The first chopper switch 1422 outputs the first pair of differential signals { P1, N1 } to the first chopper amplifier 1424.

The first chopper amplifier 1424 can be implemented based on what is shown in Fig. 3B. Thus, the first chopper amplifier 1424 includes a first amplifier A1 1302, a second chopper switch Z2 1304, and a second amplifier A2 1306. A first amplifier (A1) 1302 performs a first stage amplification of the received first pair of differential signals { P1, N1 }. Second chopper switch (Z2) (1304) is configured to switch the first to the differential signal {P1, N1} amplified by the clock half-period direct power, and a second clock half-period {P1, N1} of the differential signal amplification so as to output in the do. The second chopper switch Z2 1304 outputs a second pair of differential signals { P2, N2 }. A second pair of differential signals { P2, N2 } may be further amplified by the second amplifier (A2) 1306 before being output to the sample and hold circuit 1426. [

The sample and hold circuit 1426 is configured to sample the amplified second pair of differential signals { P2, N2 } output from the first chopper amplifier 1424 in FIG. 4 during the first clock half period and the second clock half period . The output of the sample and hold circuit 1426 includes two pairs of differential signals { P2A , N2A } and { P2B, N2B }, wherein a pair { P2A, N2A } is output during the first clock half- The pair { P2B, N2B } is output during the second clock half period.

The filter circuit 1428 removes the difference signal from the {P2A, N2A} differential signal of the two pairs and {P2B, N2B}, and amplifies the differential signal {P2A, N2A} and {P2B, N2B}, and a comparator circuit (1430) To output the third differential signal { P3, N3 }.

The comparator circuit 1430 is configured to compare the pair of reference voltage signals with the differential signal { P3, N3 } and determine the polarity of the external magnetic field based on the comparison result. The comparator circuit 1430 generates a magnetic field detection signal indicative of the determined polarity of the external magnetic field and outputs it to the output control circuit 1406. [ In a particular embodiment, the magnetic field detection signal is a switching magnetic field detection signal.

The output control circuit 1406 is configured to control the magnetic sensor to operate in one state in response to the determined polarity of the external magnetic field. The magnetic sensor can operate in a plurality of states. For example, the first state may correspond to a scenario where the load current flows through the output port 1410 from the inside to the outside of the magnetic sensor, and the second state may be such that the load current flows from the outside of the magnetic sensor through the output port 1410 It may correspond to a scenario that flows inward. In a particular embodiment, the magnetic sensor may operate in a third state where no current flows through output port 1410. [

The actual magneto voltage signal is generally very small. For example, it is smaller than millivolts. However, the deviation signal generated by the Hall detector 1420 is often higher, approximately 10 millivolts. Since the present disclosure attempts to eliminate the deviation signal and amplify the actual magneto voltage signal, the actual magneto voltage signal at the operable level can be provided to any electrical equipment using a motor or a magnetic sensor. In a particular embodiment, the voltage supply to the magnetic field detection circuit 1404 is at a level of about 2.5V. When the detection signal output by the hall detector 1420 passes through the first chopper switch 1422, the first chopper amplifier 1424, the sample and hold circuit 1426 and the filter circuit 1428, May be amplified to any number between 1000 and 2000 times the original power gain, preferably 1600 times the conventional power gain. As a result, the detected actual magnetic voltage signal is amplified to be approximately half of the voltage level supplied to the magnetic field detection circuit 1404. In certain embodiments, the first chopper amplifier 1424 is configured to achieve a gain greater than the gain of the filter circuit 1428. [ For example, the gain achieved by the first chopper amplifier 1424 may be 50 and the gain achieved by the filter circuit 1428 is 32.

FIG. 5 illustrates an exemplary schematic diagram of a rectifier circuit 1402 in accordance with one embodiment of the present disclosure. 5, the full wave rectifier bridge includes a rectifier circuit 1402 including a first diode 1502, a second diode 1504, a third diode 1506 and a fourth diode 1508, Used to implement; The voltage regulator includes a regulator diode 1520. The first diode 1502 and the second diode 1504 are connected in series. The third diode 1506 and the fourth diode 1508 are also connected in series. The anode of the first diode 1502 and the anode of the second diode 1504 are configured to connect to the input port 1408A, which supplies the voltage VAC + . The anode and cathode of the fourth diode 1508 of the third diode 1506 is configured to coupled to the input port (1408B), which voltage (VAC -) supply. The anode of the regulator diode 1502 is configured to be connected to the third diode 1506 - further connected to ground - and to the anode of the first diode 1502. The cathode of the regulator diode 1520 is connected to the cathode of the fourth diode 1508 and the second diode 1504 which are coupled together to the voltage VDD .

6 illustrates an exemplary circuit diagram of a Hall detector 1420 and a first chopper switch in accordance with one embodiment of the present disclosure. According to the illustrated embodiment, Hall detector 1420 and first chopper switch 1422 are integrated as a single circuit of Fig. Hall detector 1420 includes a Hall detection circuit board having four connection ports 1602, 1604, 1606, and 1608. The connection ports 1602 and 1606 are disposed opposite to each other and the connection ports 1604 and 1608 are disposed to face each other. First chopper switch 1422 includes four switches 1610, 1612, 1614, and 1616. The switch 1610 controls the connection ports 1602 and 1608 to be alternately connected to the power source VCC and the switch 1612 controls the connection ports 1604 and 1606 to be alternately connected to the ground. The switch 1614 controls the connection ports 1602 and 1608 to alternately output the differential signal P1 and the switch 1616 controls the connection ports 1604 and 1606 to alternately output the differential signal N1 . The hall detector 1420 and the first chopper switch 1422 are configured such that when one of the connection ports 1602 and 1608 is connected to the power supply VCC , the other of the connection ports 1602 and 1608 is a differential And outputs a signal P1 . On the other hand, when one of the connection ports 1604 and 1606 is connected to ground, the other of the connection ports 1604 and 1606 outputs the differential signal N1 . For example, when the connection port 1602 is connected to the power supply VCC and the connection port 1606, the connection ports 1608 and 1604 output a pair of differential signals { P1, N1 }. Alternatively, when the connection port 1608 is connected to the power supply VCC and the connection port 1604 to ground, the connection ports 1602 and 1606 output a first pair of differential signals { P1, N1 } .

In a particular embodiment, the power supply ( VCC ) may be a constant voltage source that is accomplished by performing voltage drop and regulation of the output of the rectifier circuit 1402. [ In another embodiment, the power supply VCC may be a constant current source.

In a particular embodiment, each of the switches 1610, 1612, 1614, and 1616 includes a pair of switches configured to be a high voltage conduction or a low voltage conduction. Each of these pairs of switches can be controlled by a pair of complementary clock signals. By respectively supplying a second pair of complementary clock signals having the same frequency to the switch (1610, 1612, 1614 and 1616), Hall detector 1420, and the first chopper switch 1422 has a first pair of differential signal {P1, N1 }. ≪ / RTI >

FIG. 7 illustrates an exemplary signal output according to the circuit diagram of FIG. The signal CK1 indicates a clock signal. The signal Vos indicates a deviation signal inherent in the Hall detector 1420. In general, the signal Vos depends on the physical characteristics of the Hall detector 1420. Vin and - Vin represent actual field voltage signals output by the first chopper switch 1422 during the first half and the second half of the clock signal CK1 , respectively. The actual magnetic field voltage signal is an ideal magnetic field voltage signal related to the external magnetic field without interference signals caused by the deviation signal. During the first half and the second half of the clock signal CK1 , the actual field voltage signal output by the first chopper switch 1422 has the same amplitude and opposite polarity. Vout represents the output of the first chopper switch 1422 which is the actual magnetic field voltage signal ( Vin or -Vin ) by or in combination with the deviation signal Vos . The first chopper switch 1422 separates the actual magnetic field voltage signal ( Vin or - Vin ) and the deviation signal ( Vos ) and switches the signal on chopper frequency and baseband frequency, respectively. In a particular embodiment, the chopper frequency is the frequency of the clock signal CK1 and the baseband frequency is the polarity that changes the frequency of the external magnetic field.

FIG. 8 illustrates an exemplary circuit diagram of a filter circuit 1428 in accordance with one embodiment of the present disclosure. The filter circuit 1428 as shown in FIG. 4 may include a first filter (F1) 1802 and a second filter (F2) 1804. The first filter (F1) 1802 is configured to apply the first stage in addition to each of the two pairs of signals { P2A , P2B } and { N2A, N2B } output from the sample and hold circuit 1426, To remove the deviation signal. The first filter (F1) 1802 may be further configured to perform the first stage gain amplification on the signal after the first stage further process. The second filter (F2) 1804 applies a second stage additive and / or a second stage gain amplification to the output signal from the first filter (F1) 1802 and adds the third stage of the differential signal { P3, N3 } / RTI > The gain of the first filter (F1) 1802 can be configured to be smaller than the gain of the second filter (F2) 1804. For example, the gain of the first filter (F1) 1802 is 4 and the gain of the second filter (F2) 1804 is 8.

It should be appreciated that the illustration of the filter circuit 1428 described above is for illustrative purposes only. The disclosure is not intended to be limiting. The filter circuit 1428 may include more or less filters than those shown in FIG. In certain embodiments, the filter circuit 1428 may comprise only one filter. However, in this situation, the unique filter may have to be configured with a large resistance to achieve a better gain.

FIG. 9 illustrates an exemplary circuit diagram of a comparator circuit 1430 in accordance with one embodiment of the present disclosure. The comparator circuit 1430 of FIG. 4 may perform the same function as the A / D conversion element 1114 of FIG. In this embodiment, the comparator circuit 1430 may be a delay comparator comprising a first comparator (C1) 1902, a second comparator (C2) 1904 and a latch logic circuit (S) The input to the first comparator (C1) 1902 includes a pair of a third pair of differential signals { P3, N3 } and a reference voltage signal { Vh , Vl }, Vh is a high voltage signal and Vl is a low voltage signal . The input to the second comparator (C2) 1904 includes the same pair of signals input to the first comparator C1 except that the pair of reference voltage signals { Vh , Vl } are connected to the opposite polarity. A first comparator (C1) 1902 is configured to compute an output voltage V1 from the filter 1408 where V1 = P3-N3 , the high voltage threshold is Rh , and Rh = Vh - Vl . The first comparator (C1) 1902 compares the output voltage V1 to the high voltage threshold Rh . When V1> Rh , the first comparator (C1) 1902 outputs a high level, and when V1 < Rh , the first comparator (C1) 1902 outputs a low level. The second comparator (C2) 1904 is configured to compare the low voltage threshold V1 with the output voltage R1 from the filter 1408, and R1 = Vl - Vh . When V1 > Rl , the second comparator (C2) 1904 outputs a high output and when V1 < Rl , the second comparator (C2) 1904 outputs a low output. When Rh is greater than Rl, V1> when Rh, V1> Rl means, and the first comparator (C1) (1902) and a second comparator (C2) (1904), and outputs high. When V1 < R1 , V1 <Rh , and the first comparator (C1) 1902 and the second comparator (C2) 1904 output low. When R1 <V1 < Rh , the first comparator (C1) 1902 outputs a low level and the second comparator (C2) 1904 outputs a high level. The comparison result from the first comparator (C1) 1902 and the second comparator (C2) 1904 is sent to the latch logic circuit (S) 1906. The latch logic circuit (S) 1906 is configured to generate a voltage signal based on the comparison result. The voltage signal is further sent to the output control circuit 1406 to control the operating state of the magnetic sensor. Details of how the latch logic circuit (S) 1906 generates the voltage signal based on the comparison result is described below.

10 illustrates an exemplary schematic diagram for determining the polarity of a magnetic field in accordance with one embodiment of the present disclosure. The latch logic circuit (S) 1906 outputs a signal from the first comparator (C1) 1902 and the second comparator (C2) 1904 indicating that the output voltage V1 of the filter circuit 1428 is greater than Rh Upon receiving the comparison result, the latch logic circuit (S) 1906 generates a first signal indicative of a change to the sink current state. The latch logic circuit (S) 1906 outputs the comparison result from the first comparator (C1) 1902 and the second comparator (C2) 1904 that indicates that the output voltage of the filter circuit 1428 is smaller than Rh Upon receipt, the latch logic circuit (S) 1906 generates a second signal indicative of a change to the source current state. The latch logic circuit (S) 1906 includes a first comparator (C1) 1902 and a second comparator (C2) that indicate that the output voltage V1 of the filter circuit 1428 satisfies Rl < 1904, the latch logic circuit (S) 1906 generates a third signal indicating that there is no state change. In a specific embodiment, the first voltage indicates that the external magnetic field exhibits a first polarity, and the second voltage indicates that the external magnetic field indicates the second polarity.

10, in a particular embodiment, when the magnetic field strength of the external magnetic field reaches the operating point Bop, the comparator circuit 1430 generates a first signal, and when the magnetic field strength of the external magnetic field is below the release point Brp The comparator circuit 1430 generates a second signal and when the magnetic field strength of the external magnetic field is between the operating point Bop and the release point Brp , the comparator circuit 1430 remains the output current without change .

11 illustrates an exemplary signal output of a clock period in accordance with one embodiment of the present disclosure. 11A, the first pair of differential signals { P1, N1 } is the output of the first chopper switch 1422 and the second pair of differential signals { P2, N2 } is the output of the first chopper amplifier 1424. [ And the third pair of differential signals P3 and N3 is the output of the filter circuit 1428. The one of the differential signals outputted from the first chopper switch 1422 during the first clock half period is { P1A, N1A } And { P1B, N1B } are a pair of differential signals output from the first chopper switch 1422 during the second clock half period. { P2A, N2A } is a pair of differential signals output from the first chopper amplifier 1424 during the first clock half- And { P2B, N2B } are a pair of differential signals output from the first chopper amplifier 1424 during the second clock half period.

As described above, Vout represents the output of the first chopper switch 1422, which is the actual magnetic field voltage signal Vin or -Vin superimposed by the deviation signal Vos . In another aspect, Vout denotes the difference between the first pair of differential signals { P1, N1 }, and P1 and N1 have the same amplitude and opposite polarity. Therefore, P1A , P1B , N1A and N1B are represented by the following equations:

(1).

(One).

When first chopper amplifier 1424 of FIG. 4 implements the embodiment shown in FIG. 3B, first chopper amplifier 1424 includes first amplifier 1302, second chopper switch Z2 1304, And a second amplifier (A 2) 1306. The first pair of differential signals { P1, N1 } are amplified to the differential signals { P1 ', N1' } after passing through the first amplifier A1 1302. { P1 ', N1' } and the first clock half- And its individual components during the second clock half-cycle are represented by the following equations: &lt; RTI ID = 0.0 &gt;

(2).

(2).

A represents the amplification gain of the first amplifier (A1) 1302. [ Voff represents the deviation signal output by the first amplifier (A1) 1302, which is applied to the Hall detector 1420 And a deviation signal generated by the first amplifier A1302 . For illustrative purposes, the coefficients A and &lt; RTI ID = 0.0 &gt; 1 &lt; / RTI &gt;

2 a chopper switch (Z2) (1304) is directly first differential signal {P1, N1} of outputs, the differential signal {P1, N1} amplified with the second clock half-period of the second amplifier to the clock half-period switching formula And the output from the second chopper switch Z2 1304 includes two components in each clock half-cycle. After passing through the sample and hold circuit 1426, the four components { P2A , P2B , N2A , N2B } represented by the following equations are input to the filter circuit 1428.

(3).

(3).

The third pair of differential signals { P3, N3 } output by the filter circuit 1428 is also represented by the following equation:

(4).

(4).

As shown in the above equation, the third pair of deviation signals of the differential signals { P3, N3 } are removed by the filter circuit 1428. [ The third pair of differential signals { P3, N3 } therefore comprises only the actual magnetic field voltage signal.

Figure 11B illustrates that each separated into a base band frequency of the first chopper switch, the actual magnetic field voltage signal (Vin) and the deviation signal (Voff), and then (e.g., 1202 of Fig. 2) of 400 k Hz chopper frequency and a 100 Hz Where the chopper frequency is the frequency of the clock signal. After the second chopper switch (e.g., 1304 in FIGS. 3A and 3B), the actual magnetic field voltage signal Vin and the deviation signal Voff are switched to the baseband frequency and the chopper frequency, respectively. Then, after the filter circuit (e.g., 1206 in FIG. 2), the deviation signal Voff is filtered out. When the magnetic sensor is implemented to control a synchronous motor, the external magnetic field may be a permanent magnet motor field, where the polarity change frequency is twice the AC power source frequency. If the AC power provided by the city of 50 Hz or 60 Hz in the synchronous motor, the baseband frequency is 100 Hz or 120 Hz. After passing through a number of chopper switches and amplifiers, the actual magnetic field voltage signal and the deviation signal are separated at a very wide frequency. As such, the chopper amplifiers implemented in this disclosure are configured to accommodate a very wide frequency range.

12 shows an exemplary circuit diagram of an output control circuit 1406 according to one embodiment of the present disclosure. The output control circuit 1406 according to the illustrated embodiment includes a first switch 2202 and a second switch 2204. The first switch 2202 is coupled to the output port 1410 to form the first current path and the second switch 2204 is coupled to the output port 1410 to form the second current path. The current flows in the opposite direction through the first current path and the second current path. The first switch 2202 and the second switch 2204 are selectively controlled by a magnetic detection signal to be connected. In a particular embodiment, the first switch 2202 is a transistor and the second switch 2204 is a diode or a transistor.

In a particular embodiment, the first switch 2202 is configured as a low voltage pass and the second switch 2204 is configured as a high voltage pass. The control end of both the first switch 2202 and the second switch 2204 is connected to the output of the magnetic detection circuit 1404. The output of the first switch 2202 and the input of the second switch 2204 are all connected to the output port 1410. The input of the first switch 2202 may be coupled to the high voltage end 2206, such as an output ( VDD ) from the rectifier circuit 1402 or a DC power source, and the output of the second switch 2204 may be, Voltage end 2208 as shown in FIG.

When the output of the magnetic detection circuit 1404 is a low voltage signal, the first switch 2202 is connected and the second switch 2204 is disconnected. As a result, the load current flows from the high voltage end 2206 into the first switch 2202 and flows out through the output port 1410. When the output of the magnetic detection circuit 1404 is a high voltage signal, the second switch 2204 is connected, and the first switch 2202 is disconnected. As a result, the load current flows from the output port 1410 into the second switch 2204 and flows out through the low voltage end 2208. [

Figure 13 shows an exemplary circuit diagram of an output control circuit according to another embodiment of the present disclosure. The output control circuit 1406 according to the illustrated embodiment includes a first switch 2302 and a second switch 2304. The first switch 2302 is configured as a high voltage path and the second switch 2304 is configured as a unidirectional diode. The control end of the first switch 2302 and the cathode of the second switch 2304 are all connected to the output of the magnetic detection circuit 1404. In a particular embodiment, the control end of the first switch 2302 is coupled to the output of the magnetic detection circuit 1404 via a resistor 2308. The input of the first switch 2302 may be coupled to the output of the rectifier circuit 1402 (see FIG. 4). The output of the first switch 2302 and the anode of the second switch are all connected to the output port 1410. 12, a first switch 2302 is coupled to an output port 1410 to form a first current path, and a second switch 2304 is coupled to an output port 1410 to form a second current path. Similarly to the embodiment shown in FIG. 12, Gt; 1410 &lt; / RTI &gt; The current flows through the first and second current paths in opposite directions. When the output of the magnetic detection circuit 1404 is a high voltage signal, the first switch 2302 is connected and the second switch 2304 is disconnected. As a result, the load current flows from the high voltage end 2306 into the first switch 2302, and flows out through the output port 1410. [ When the output of the magnetic detection circuit 1404 is a low voltage signal, the second switch 2304 is connected and the first switch 2302 is disconnected. As a result, the load current flows from the output port 1410 into the second switch 2304.

Figure 14 illustrates an exemplary circuit diagram of an output control circuit in accordance with another embodiment of the present disclosure; The output control circuit 1406 of the illustrated embodiment includes a unidirectional switch 2402 and a resistor 2404. The unidirectional switch 2402 is connected between the magnetic field detection circuit 1404 and the output port 1410 to form a first current path and the resistor 2404 is connected between the magnetic field detection circuit 1404 and the output port 1410 to form a second current path. (1410), where the current flows through the first and second current paths in opposite directions. When the output of the magnetic detection circuit 1404 is a high voltage signal, the unidirectional switch 2402 is connected and the load current flows from the output of the magnetic field detection circuit 1404 through the unidirectional switch 2402 to the output port 1410. When the output of the magnetic detection circuit 1404 is a low voltage signal, the unidirectional switch 2402 is disconnected and the load current flows from the output port 1410 through the resistor 2404 to the output of the magnetic detection circuit 1404.

The magnetic sensors of the present disclosure can be connected directly to a city AC power source that does not require additional A / D conversion equipment. Therefore, the present disclosure enables the implementation of magnetic sensors in various fields. In addition, the magnetic field detection circuit can efficiently amplify the detected magnetic field signal and filter the interference signal by adjusting the voltage. Therefore, the magnetic sensor can generate a more accurate signal about the polarity of the external magnetic field to control the operation of the electric rotor.

Figure 15 shows an exemplary schematic diagram of a motor 2500 incorporating a magnetic sensor constructed in accordance with the present disclosure. The motor may include an AC power supply 2502, a motor 2504, a magnetic sensor 2508 and a bi-directional switch 2510. The motor 2500 may further include a voltage drop circuit 2506 configured to remove the level of the AC power supply 2502 before providing it to the magnetic sensor 2508. [ The output ( Pout ) of the magnetic sensor 2508 is electrically connected to the control end of the bi-directional switch 2510.

In a particular embodiment, the magnetic sensor 2508 is operable when the AC power source 2502 is operating in a positive half-cycle and when the magnetic field detection circuit 1404 of the magnetic sensor 2508 determines that the external magnetic field exhibits a first polarity, And outputs a driving current to the driving circuit 2510. Alternatively, the output control circuit 1406 of the magnetic sensor 2508 is operable when the AC power source 2502 is operating in a negative half-cycle and when the magnetic field detection circuit 1404 detects that the external magnetic field has a second polarity opposite the first polarity The magnetic sensor 2508 is configured to output the driving current to the bidirectional switch 2510. [ The output control circuit 1406 of the magnetic sensor 2508 is activated when the AC power supply 2502 operates in a negative half period and the magnetic field detection circuit 1404 determines that the external magnetic field exhibits the first polarity, Directional switch 2510 when the magnetic field detection circuit 1404 determines that the magnetic field detection circuit 1404 is operating at the positive half period and that the magnetic field detection circuit 1404 indicates the second polarity.

In the embodiment in which the magnetic sensor 2508 uses the rectifier circuit shown in Fig. 5 and the output control circuit shown in Fig. 12, the input of the first switch 2202 in Fig. 12 is the voltage output of the bridge full- ( VDD ) and the output of the second switch 2204 is configured to connect to ground. When the AC power supply 2502 operates in the positive half-cycle and the magnetic field detection circuit 1404 outputs the low voltage, the first switch 2202 is connected and the second switch is disconnected and the current is supplied to the AC power supply 2502, the motor 2504, VAC + , magnetic sensor 2508 and bi-directional switch 2510. [ Within the magnetic sensor 2508, current flows through the voltage output of the bridge full wave rectifier and the first switch 2202. In a particular embodiment, the current flows through the voltage drop circuit 2506 before the magnetic sensor 2508.

When the AC power source 2502 operates in a negative half-cycle and the magnetic field detection circuit 1404 outputs a high voltage, the first switch 2202 is disconnected and the second switch is connected and the current is supplied to the AC power source 2502, The magnetic sensor 2508, and the motor 2504 in the opposite direction. In the magnetic sensor 2508, current flows through the second switch 2204, the ground output of the bridge full-wave rectifier, the first diode 1502, and VAC + . When the AC power supply 2502 operates in the positive half-cycle and the magnetic field detection circuit 1404 outputs a high voltage or when the AC power supply 2502 operates in the negative half-cycle and the magnetic field detection circuit 1404 outputs the low voltage, 1 switch 2202 and the second switch 2204 are all separated. As a result, there is no driving current flowing through Pout of the magnetic sensor 2508. [

16 illustrates an exemplary schematic diagram of a synchronous motor 2600 incorporating a magnetic sensor constructed in accordance with the present disclosure. The synchronous motor 2600 includes a stator 2602 and a rotor 2602 configured to rotate relative to the stator. The stator includes a stator core 2604 and a stator coil 2612 configured to wind around the stator core 2604. The stator core 2604 may be comprised of any soft magnetic material, such as iron, cast iron, electric steel, silicon, and the like. The rotor 2602 is configured to rotate at a constant speed (i.e., revolutions per minute, rpm) of 60 f / p when the AC power source is connected in series, where f is the frequency of the AC power source and p is the rotor 2602). Stator core 2604 is comprised of opposite pole portions 2608A and 2608B. Each of the pairs of opposing pole portions 2608A and 2608B has a very large surface, e.g., 2610A and 2610B. The surface of the rotor 2602 is opposite to the extreme surfaces 2610A and 2610B and forms a gap 2606 therebetween. In a particular embodiment, the gap 2606 between the rotor 2602 and the stator is substantially uniform with very small uneven gap areas. In a particular embodiment, each of the pole surfaces 2610A, 2610B is further comprised of a start groove, e.g., 2614. The extreme surfaces 2610A and 2610B are concentric with the rotor 2602 except in the region of the starting groove. The configuration of the starting groove forms an uneven magnetic field inside. The configuration of the starting groove is also such that the pole S1 of the rotor 2602 is inclined at an angle to the center pole S2 of the pole portions 2608A and 2608B when the rotor 2602 is at rest. This configuration allows the rotor 2602 to have a starting torque every time the motor is turned on. In this embodiment, the pole S1 of the rotor 2602 is the separation boundary between the two poles of the rotor 2602 and the center pole S2 passes through the central opposite pole portions 2608A and 2608B do. The stator and rotor 2602 are all configured with two magnetic poles.

The output control circuit 1406 according to the present disclosure controls the bidirectional switch 2510 to switch the state between connection and disconnection based on the polarity of the AC power supply 2502 and the polarity of the external magnetic field, And controls the power increase state. As such, the magnetic field generated by the stator can be coordinated with the magnetic field position of the rotor 2602 to drive the rotor to rotate in one unidirectional direction and ensure that the motor has a constant rotational direction each time the motor power increases have.

Thus, an application device is additionally provided according to one embodiment of the present disclosure. The application device includes a motor powered by AC power, a bidirectional conduction switch electrically connected in series to the electric motor, and a magnetic sensor integrated circuit according to any one of the above embodiments. The output port of the magnetic sensor integrated circuit is electrically connected to the control end of the bidirectional conduction switch. Alternatively, the application device may be a pump, a fan, an appliance, a vehicle, or the like, and the appliance may be, for example, a washing machine, a dishwasher, a range hood, an exhaust fan, and the like.

It should be understood that the above-described embodiments are for illustrative purposes only. The disclosure is not intended to be limiting. The stator and rotor 2602 may be configured with different stimuli such as four or six stimuli. Further, the stator and rotor 2602 may have different stimuli with respect to each other.

Those skilled in the art will recognize that the disclosure may be adapted for various modifications and / or improvements. For example, as described herein with the host device, the client node may be implemented as firmware, firmware / software combination, firmware / hardware combination, or hardware / firmware / software combination. While the implementation of the various components described above may be implemented in a hardware device, it may also be implemented as a software-only solution, e.g., an installation on an existing server. Further, the unit and client nodes of the host may be implemented as firmware, firmware / software combination, firmware / hardware combination, or hardware / firmware / software combination as disclosed herein.

While the foregoing is considered to be the best mode and / or example, it is to be understood that various modifications may be made and the objects disclosed herein may be implemented in various forms and embodiments, , Only some of which are described herein. It is intended by the following claims to cover any and all applications, modifications and variations that fall within the true scope of the disclosure.

Claims (11)

As a magnetic sensor,
An input port connected to an external power source;
A magnetic field detection circuit configured to generate a magnetic detection signal;
An output control circuit configured to control an operation of the magnetic sensor in response to the magnetic detection signal; And
Output port,
The magnetic field detection circuit comprising:
A magnetic sensing element configured to detect an external magnetic field and output a detection signal,
A signal processing element configured to amplify the detection signal and remove interference from the detection signal to produce a processed detection signal; and
And a conversion element configured to convert the processed detection signal into the magnetic detection signal used for controlling the magnetic sensor to operate in at least one of a first state and a second state responsive to at least the magnetic detection signal,
In the first state, a load current flows out from the output port of the magnetic sensor to the outside,
And in the second state, a load current flows from the outside of the magnetic sensor into the output port. The apparatus of claim 1, wherein the detection signal includes a magnetic field signal and a deviation signal,
Wherein the signal processing element comprises:
A first chopper switch configured to separate the detection signal into the deviation signal and the magnetic field signal corresponding to a chopper frequency and a baseband frequency, respectively,
A chopper amplifier configured to amplify the deviation signal and the magnetic field signal and to switch the amplified deviation signal and the amplified magnetic field signal to the chopper frequency and the base band frequency, respectively;
And filter circuitry configured to filter out the deviation signal at the chopper frequency. The chopper amplifier according to claim 2, wherein the chopper amplifier
The first amplifier and
And a second chopper switch,
The first amplifier includes a folded cascade amplifier for performing the first stage amplification on the deviation signal and the magnetic field signal from the first chopper switch to generate the amplified deviation signal and the amplified magnetic field signal, Including,
And the second chopper switch is configured to switch the amplified deviation signal and the amplified magnetic field signal to the chopper frequency and the baseband frequency, respectively. 4. The amplifier of claim 3, wherein the chopper amplifier further comprises a second amplifier connected in series to the second chopper switch,
Wherein the second amplifier is configured to perform a second stage amplification on the amplified deviation signal switched to the chopper frequency and the amplified magnetic field signal switched to the baseband frequency. The signal processing device according to claim 2,
Further comprising a sample-and-hold circuit coupled between the chopper amplifier and the filter circuit,
Wherein the sample and hold circuit is configured to sample a first pair of differential signals during a first clock half period and a second clock half period, respectively, and to output two pairs of sampled differential signals during a clock period. The filter circuit of claim 5, wherein the filter circuit further comprises: a first filter configured to compute a second pair of differential signals based on two pairs of sampled differential signals; and a second filter configured to further amplify the second pair of differential signals, And to generate a third pair of differential signals. &Lt; Desc / Clms Page number 20 &gt; 3. The device of claim 2, wherein the conversion element comprises:
A first comparator configured to compare an output voltage determined based on a high voltage threshold and a third pair of differential signals;
A second comparator configured to compare the output voltage with a low voltage threshold; And
To output a first voltage when the output voltage is greater than the high voltage threshold or to output a second voltage when the output voltage is less than the low voltage threshold, And a latch logic circuit configured to maintain the output of the conversion element if it is between a high voltage threshold, the high voltage threshold and the low voltage threshold being determined based on a differential voltage reference pair,
Wherein the first comparator and the second comparator take as inputs a pair of differential voltage references and a third pair of differential signals from the filter circuit. 7. The apparatus of claim 6, wherein the latch logic circuit is configured to output a first voltage when the magnetic field strength reaches a predetermined operating point or to output a second voltage when the magnetic field strength does not reach a predetermined release point, And to maintain the output of the conversion element when a magnetic field strength is between the predetermined release point and the predetermined operating point. The method according to claim 1,
A rectifier circuit coupled to the input port and configured to provide a voltage supply to the magnetic field detection circuitry;
And an output control circuit configured to control the magnetic sensor to operate in at least one of the first state and the second state based on the switching detection signal,
The output control circuit comprising:
A first switch coupled to the output port to form a first current path that allows the load current to flow from the output port to the outside of the magnetic sensor in the first state; And
And a second switch coupled to the output port to form a second current path that allows the load current to flow from the outside of the magnetic sensor to the output port in the second state,
Wherein the first switch and the second switch operate based on the switching detection signal to selectively turn on the first current path and the second current path. An integrated circuit for a magnetic sensor,
An input port connected to an external power source;
Output port; And
A magnetic field detection circuit configured to generate a magnetic detection signal, the magnetic field detection circuit comprising:
A magnetic sensing element configured to detect an external magnetic field and output a detection signal, the detection signal including a magnetic field signal and a deviation signal,
A signal processing element configured to amplify the detection signal and remove interference to produce a processed detection signal; and
And a conversion element configured to convert the processed detection signal into the switching detection signal used for controlling the magnetic sensor to operate in at least one of a first state and a second state responsive to at least the switching detection signal,
Wherein the signal processing element comprises:
A first chopper switch configured to separate the detection signal into a deviation signal and a magnetic field signal corresponding to a chopper frequency and a baseband frequency, respectively,
A chopper amplifier configured to separately amplify the deviation signal and the magnetic field signal, and to switch the amplified deviation signal and the amplified magnetic field signal to the chopper frequency and the base band frequency, respectively; And
And a filter circuit configured to remove the deviation signal switched to the chopper frequency. A motor assembly, comprising: a motor powered by ac power; and a magnetic sensor as claimed in any one of claims 1 to 9 or the integrated circuit for the magnetic sensor as claimed in claim 10.

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