CN110045303A - Sensing magnetic fields module - Google Patents

Abstract

The present invention provides a kind of field sensing unit and sensing magnetic fields module.Wherein field sensing unit, including substrate, the first field sensing unit, the second field sensing unit, third field sensing unit and switching circuit.Substrate has surface and this opposite surface inclined first inclined-plane and the second inclined-plane in different directions.First field sensing unit includes multiple magnetoresistive sensors for connecting into wheatstone full-bridge and be configured on this surface.Second field sensing unit includes multiple magnetoresistive sensors for connecting into wheatstone half-bridge and be configured on the first inclined-plane.Third field sensing unit includes multiple magnetoresistive sensors for connecting into wheatstone half-bridge and be configured on the second inclined-plane.Switching circuit is electrically connected the second field sensing unit and third field sensing unit.A kind of sensing magnetic fields module is also suggested.The present invention has more simplified structure, and lesser volume.

Description

Sensing magnetic fields module

The application is original application application number 201610220380.9, the applying date on 04 11st, 2016, entitled " magnetic The divisional application of field sensing device and sensing magnetic fields module ".

Technical field

The present invention relates to a kind of field sensing unit and sensing magnetic fields modules.

Background technique

With popularizing for portable electronic devices, the technology that can incude the electronic compass of magnetic direction is just taken seriously. When electronic compass is applied to portable electronic devices (such as smartphone) small in size, electronic compass is in addition to that need to meet volume Except small demand, it can also preferably reach the sensing of three axis, this is because when user holds mobile phone with hand, it may be possible to incline Tiltedly hold, and a variety of different gripping angles also all there may be.

A kind of known technology is the sensing for reaching three axis using the method for combined type sensing component, specifically, it is sharp With two giant magnetoresistances configured vertically (giant magnetoresistance, GMR) multi-layer film structure (or tunnel magneto-resistance (tunneling magnetoresistance, TMR) multi-layer film structure) it is reached with a Hall subassembly (Hall element) To the sensing of three axis.However, since the sensing sensitivity of Hall subassembly is different from gmr multilayer membrane structure, (or tunnel magneto-resistance is more Film structure) sensing sensitivity, it is different from the accuracy on other two axis that this will cause the accuracy on a wherein axis.So One, when user rotates portable electronic devices to different angles, will lead to the sensing sensitivity in same magnetic field not Together, it in turn results in and uses upper puzzlement.

In known technology, in order to which the multiaxis for reaching magnetic field senses, processing procedure more than two times is generally employed, that is, adopt Polyaxial sensing magnetic fields module is produced with the processing procedure of two pieces or more of wafer, will so processing procedure be made to complicate, and be difficult to Reduce cost of manufacture.In addition, so field sensing unit is also made to be difficult to further reduce.

Summary of the invention

The present invention provides a kind of field sensing unit, has more simplified structure, and can have lesser volume.

The present invention provides a kind of sensing magnetic fields module, has more simplified structure, and can have lesser volume.

One embodiment of the invention proposes a kind of field sensing unit, including substrate, the first field sensing unit, the second magnetic Field sensing unit, third field sensing unit and switching circuit.There is substrate surface and this opposite surface to tilt in different directions The first inclined-plane and the second inclined-plane.First field sensing unit includes multiple connecting into wheatstone full-bridge (Wheatstone full ) and the magnetoresistive sensor that is configured on this surface, and the magnetic-field component to sense first direction bridge.Second sensing magnetic fields Unit includes multiple connecting into wheatstone half-bridge (Wheatstone half bridge) and being configured at the magnetic resistance on the first inclined-plane Sensor.Third field sensing unit includes multiple magneto-resistive transducings for connecting into wheatstone half-bridge and be configured on the second inclined-plane Device.Switching circuit is electrically connected the second field sensing unit and third field sensing unit, and to by the second sensing magnetic fields list Member and the third field sensing unit wheatstone full-bridge that switch to two different.Two different wheatstone full-bridges to feel respectively Survey the magnetic-field component of second direction and the magnetic-field component of third direction.

In one embodiment of this invention, the first field sensing unit, the second field sensing unit and third sensing magnetic fields These magnetoresistive sensors of unit are anisotropic magnetoresistive sensor (anisotropic magnetoresistance sensor,AMR sensor)。

In one embodiment of this invention, first direction, second direction and third direction are substantially perpendicular each other.

In one embodiment of this invention, first direction, second direction and third direction two each other not at least within Vertically.

In one embodiment of this invention, the sensitive axis of these magnetoresistive sensors of the second field sensing unit is substantially flat Row is in the inclination extending direction on the first inclined-plane, and the sensitive axis of these magnetoresistive sensors of third field sensing unit is substantially flat Row is in the inclination extending direction on the second inclined-plane.

In one embodiment of this invention, the sensitive axis of these magnetoresistive sensors of the first field sensing unit is substantially hung down Directly in the inclination extending direction on the first inclined-plane, and perpendicular to the inclination extending direction on the second inclined-plane.

In one embodiment of this invention, field sensing unit further includes the first direction of magnetization assignment component and the second magnetization Direction assignment component.First direction of magnetization assignment component is configured at by the first field sensing unit, and to set the first magnetic field The direction of magnetization of these magnetoresistive sensors of sensing unit.Second direction of magnetization assignment component is configured at the second field sensing unit By third field sensing unit, and these magnetic resistance to set the second field sensing unit and third field sensing unit pass The direction of magnetization of sensor.

One embodiment of the invention proposes a kind of sensing magnetic fields module, including field sensing unit and direction of magnetization setting group Part.Field sensing unit includes multiple magnetoresistive sensors for connecting into Wheatstone bridge, and the magnetic field to sense a direction is divided Amount.Direction of magnetization assignment component is configured at by field sensing unit, and these magneto-resistive transducings to set field sensing unit The direction of magnetization of device.Direction of magnetization assignment component includes the first helical form conductive unit, the second helical form conductive unit and third Helical form conductive unit.Second helical form conductive unit is electrically connected at the first helical form conductive unit and third helical form is conductive Between unit, and the direction that extends spirally of the second helical form conductive unit is different from extending spirally for the first helical form conductive unit Direction, and direction is extended spirally different from third helical form conductive unit.

In one embodiment of this invention, when electric current sequentially flows through the first helical form conductive unit, the second helical form conduction When unit and third helical form conductive unit, belong to the surface or just of these magnetoresistive sensors of a half-bridge of Wheatstone bridge The current direction first direction of lower section, belong to these magnetoresistive sensors of another half-bridge of Wheatstone bridge surface or just under The current direction second direction of side, wherein first direction is in contrast to second direction.

One embodiment of the invention proposes a kind of sensing magnetic fields module, including field sensing unit and direction of magnetization setting group Part.Field sensing unit includes multiple magnetoresistive sensors for connecting into Wheatstone bridge, and the magnetic field to sense a direction is divided Amount.Direction of magnetization assignment component is configured at by field sensing unit, and these magneto-resistive transducings to set field sensing unit The direction of magnetization of device.Direction of magnetization assignment component includes that multiple first conductive segments, multiple second conductive segments, multiple first conductions are passed through Hole and multiple second conductive through holes.These first conductive segments are configured at the upside of field sensing unit and the side of downside, and this A little second conductive segments are configured at the upside of field sensing unit and the other side of downside.These first conductive through holes by part this A little first conductive segments and these partial second conductive segments connect into the first helical form conductive unit, and these second conductive through holes These second conductive segments of these first conductive segments of another part and another part are connected into the second helical form conductive unit, Wherein the direction that extends spirally of the first helical form conductive unit extends spirally direction different from the second helical form conductive unit.

In one embodiment of this invention, one of these first conductive segments are U-shaped conductive segment, a part of U-shaped conductive segment Belong to the first helical form conductive unit, and another part of U-shaped conductive segment belongs to the second helical form conductive unit.

In one embodiment of this invention, these first conductive segments partly overlap with these second conductive segments.

In the field sensing unit of the embodiment of the present invention, due to the second field sensing unit and third sensing magnetic fields list Member can switch to two different wheatstone full-bridges via circuit, to sense the magnetic field point of second direction and third direction respectively Amount, therefore field sensing unit can sense the magnetic-field component in three directions using less magnetoresistive sensor.So One, it just can simplify the framework of field sensing unit, and reduce the volume of field sensing unit.In the embodiment of the present invention In sensing magnetic fields module, direction is extended spirally different from the first helical form conductive unit due to the second helical form conductive unit Direction is extended spirally, and extends spirally direction different from third helical form conductive unit, therefore can use simple three Spiral conductive unit can effectively set the direction of magnetization of these magnetoresistive sensors of field sensing unit, therefore of the invention The framework of the sensing magnetic fields module of embodiment is simple, and volume can be smaller.In the sensing magnetic fields module of the embodiment of the present invention In, due to the side of extending spirally for extending spirally direction and being different from the second helical form conductive unit of the first helical form conductive unit To, therefore magnetic can effectively can be set using simple multiple first conductive segments, multiple second conductive segments and conductive through hole The direction of magnetization of these magnetoresistive sensors of field sensing unit.So the framework of the sensing magnetic fields module of the embodiment of the present invention Simply, and volume can be smaller.

To make the foregoing features and advantages of the present invention clearer and more comprehensible, special embodiment below, and cooperate institute's accompanying drawings It is described in detail below.

Detailed description of the invention

Figure 1A is the stereoscopic schematic diagram of the field sensing unit of one embodiment of the invention；

Figure 1B is the diagrammatic cross-section of the field sensing unit of Figure 1A；

Fig. 1 C is the explosive view of the sensing magnetic fields module in Figure 1A；

The second field sensing unit and third field sensing unit that Fig. 2A is Figure 1A are when sensing the direction y magnetic-field component Equivalent circuit diagram；

The second field sensing unit and third field sensing unit that Fig. 2 B is Figure 1A are when sensing the direction z magnetic-field component Equivalent circuit diagram；

Fig. 3 is the explosive view of the sensing magnetic fields module of another embodiment of the present invention；

Fig. 4 is the explosive view of the sensing magnetic fields module of another embodiment of the present invention；

Fig. 5 is the explosive view of the sensing magnetic fields module of one more embodiment of the present invention.

Appended drawing reference:

100: field sensing unit

110: substrate

112: surface

114: the first inclined-planes

116: the second inclined-planes

120: the first field sensing units

122,122a, 122b, 122c, 122d, 132,132a, 132b, 142,142a, 142b: magnetoresistive sensor

123: anisotropic magnetoresistance

125: ferromagnetic film

127: short bar

130: the second field sensing units

140: third field sensing unit

150: switching circuit

200,200a, 200b, 200c: the first direction of magnetization assignment component

210,250a, 250b, 250c: the first helical form conductive unit

210a, 211~213,211b~214b, the 211c~215c: the first conductive segment

2121,2131c, 2221b: first part

2122,2132c, 2222b: second part

220,260a, 260b, 260c: the second helical form conductive unit

220a, 221,222,221b~223b, the 221c~224c: the second conductive segment

230: third helical form conductive unit

230a, 231,232,231b~233b, the 231c~234c: the first conductive through hole

240,250,260: conductive segment

240a, 241,242,241b~243b, the 241c~244c: the second conductive through hole

270a, 280a: contact

300: the second direction of magnetization assignment components

400,400a, 400b, 400c, 500: sensing magnetic fields module

A1, A2, A3: sensitive axis

C1, C2, C3, C4, C5, C6: endpoint

D1: inclination extending direction

D2: inclination extending direction

E1, E2, E2, E4, E5, E6: current direction

P1, P2, P3, P4, P5, P6, P7, P8, Q1, Q2, Q3, Q4: endpoint

Specific embodiment

Figure 1A is the stereoscopic schematic diagram of the field sensing unit of one embodiment of the invention, and Figure 1B is the sensing magnetic fields of Figure 1A The diagrammatic cross-section of device, and Fig. 1 C is the explosive view of the sensing magnetic fields module in Figure 1A, wherein for ease of description, Tu1AZhong The direction of magnetization assignment component in Figure 1B is omitted.Figure 1A to Fig. 1 C is please referred to, the field sensing unit 100 of the present embodiment includes Substrate 110, the first field sensing unit 120, the second field sensing unit 130, third field sensing unit 140 and switching circuit 150 (as shown in Figure 1B).Substrate 110 has surface 112 and apparent surface 112 inclined first inclined-plane 114 in different directions With the second inclined-plane 116.In the present embodiment, substrate 110 is, for example, silicon substrate (blank silicon), the glass substrate of blank Or there is super large-scale integration (very large scale integrated-circuit, VLSI) or large-scale integrated The silicon substrate of circuit (large scale integrated-circuit, LSI).

First field sensing unit 120 includes that multiple magnetic resistance for connecting into wheatstone full-bridge and being configured on surface 112 pass Sensor 122, and the magnetic-field component to sense first direction (such as the direction x).Second field sensing unit 130 includes multiple companies The magnetoresistive sensor 132 for being connected into wheatstone half-bridge and being configured on the first inclined-plane 114.Third field sensing unit 140 includes more A magnetoresistive sensor 142 for connecting into wheatstone half-bridge and be configured on the second inclined-plane 116.Switching circuit 150 is electrically connected the Two field sensing units 130 and third field sensing unit 140, and to by the second field sensing unit 130 and third magnetic field Sensing unit 140 switches to two different wheatstone full-bridges.Two different wheatstone full-bridges to sense second party respectively To the magnetic-field component in (such as the direction y) and the magnetic-field component in third direction (such as the direction z).In the present embodiment, the direction x, the side y To vertical each other with the direction z.In other words, in the present embodiment, first direction, second direction and third direction are substantive each other It is upper vertical.However, in other embodiments, first direction, second direction and third direction at least within two do not hang down each other Directly, and first direction, second direction and third direction it is different from each other to.In the present embodiment, the direction x and the direction y be substantially all It is parallel to the surface 112 of substrate 110, and the direction z is perpendicular to the surface 112 of substrate 110.

In the present embodiment, the first field sensing unit 120, the second field sensing unit 130 and third sensing magnetic fields list These magnetoresistive sensors 122,132 and 142 of member 140 are anisotropic magnetoresistive sensor (anisotropic magnetoresistance sensor,AMR sensor).However, in other embodiments, these magnetoresistive sensors 122, It 132 and 142 can also be giant magneto-resistance sensor (giant magnetoresistance sensor, GMR sensor), tunneling Magnetoresistive sensor (tunneling magnetoresistance sensor, TMR sensor), fluxgate (flux gate) or Magneto-impedance sensors (magneto-impedance sensor).

In the present embodiment, the sensitive axis A1 of these magnetoresistive sensors 122 of the first field sensing unit 120 substantially hangs down Directly in the inclination extending direction D1 on the first inclined-plane 114, and perpendicular to the inclination extending direction D2 on the second inclined-plane 116, as Figure 1A with Shown by Fig. 1 C.Specifically, in the present embodiment, each magnetoresistive sensor 122 may include multiple concatenated anisotropic magnetics Resistance (anisotropic magnetoresistor) 123, the extending direction of each anisotropic magnetoresistance 123 are substantially flat Row is in the direction y, and the short axle of each anisotropic magnetoresistance 123 is substantially parallel to the direction x, and this short axle is magneto-resistive transducing The sensitive axis A1 of device 122.

The direction of magnetization of magnetoresistive sensor 122a and magnetoresistive sensor 122b is, for example, the direction direction-y in the present embodiment, The direction of magnetization of magnetoresistive sensor 122c and magnetoresistive sensor 122d is, for example, towards the direction+y.In addition, each anisotropic magnetic Resistance 123 has barber's pole (barber pole) shape structure, that is, its surface is equipped with relative to anisotropic magnetoresistance 123 extending direction (for example, direction y) tilts multiple short bars (electrical shorting bar) of 45 degree of extensions 127, these short bars are spaced apart and are set in parallel on ferromagnetic film (ferromagnetic film) 125, and ferromagnetic Film 125 is the main body of anisotropic magnetoresistance 123, and extending direction is the extending direction of anisotropic magnetoresistance 123.At this In embodiment, the extension of the short bar 127 of the extending direction and magnetoresistive sensor 122c of the short bar 127 of magnetoresistive sensor 122a Direction is substantially the same, the extending direction of the short bar 127 of magnetoresistive sensor 122b and the short bar 127 of magnetoresistive sensor 122d Extending direction it is substantially the same, and the extending direction of the short bar 127 of magnetoresistive sensor 122a be different from magnetoresistive sensor The extending direction of the short bar 127 of 122b, two are, for example, 90 degree of difference.

By the setting in 127 direction of the direction of magnetization and short bar of above-mentioned magnetoresistive sensor 122a~122d, when external magnetic When there is magnetic-field component in the direction+x, the resistance of magnetoresistive sensor 122b and 122c has+variation of Δ R, and magnetoresistive sensor The resistance of 122a and 122d has-variation of Δ R, so when endpoint Q1 and endpoint Q2 are applied voltage difference, endpoint Q3 and end Point Q4 will have voltage difference, and the size of the size of this voltage difference and the direction x magnetic-field component is presented and is positively correlated.In this way, The size of the direction x magnetic-field component, such first sensing magnetic fields list can be learnt by the voltage difference of endpoint Q3 and endpoint Q4 Member 120 can realize the sensing of the direction x magnetic-field component.

The setting in 127 direction of the direction of magnetization and short bar of magnetoresistive sensor 122a~122d is not limited to above-mentioned setting Mode, in other embodiments, the direction of magnetization of magnetoresistive sensor 122a~122d and 127 direction of short bar can also have other Configure the setting on direction, if when with the presence of the direction x magnetic-field component and endpoint Q1 and endpoint Q2 be applied voltage difference when, endpoint Q3 and endpoint Q4 can generate voltage difference, as long as or when with the presence of the direction x magnetic-field component and endpoint Q3 is applied with endpoint Q4 When voltage difference, endpoint Q1 and endpoint Q2 can generate voltage difference.

In the present embodiment, the sensitive axis A2 of these magnetoresistive sensors 132 of the second field sensing unit 130 is substantially flat It goes in the inclination extending direction D1 on the first inclined-plane 114, and the sense of these magnetoresistive sensors 142 of third field sensing unit 140 Axis A3 is surveyed substantially parallel to the inclination extending direction D2 on the second inclined-plane 116.Specifically, each magnetoresistive sensor 132 is more The extending direction of a anisotropic magnetoresistance being one another in series substantially parallel to the direction x, and these anisotropic magnetoresistances that This is arranged on the first inclined-plane 114 in parallel and along inclination extending direction D1.In addition, the short circuit of each magnetoresistive sensor 132 The extending direction of stick and the extending direction of anisotropic magnetoresistance press from both sides 45 degree.In addition, each magnetoresistive sensor 142 it is multiple each other The extending direction of concatenated anisotropic magnetoresistance is substantially parallel to the direction x, and these anisotropic magnetoresistances are parallel to each other Ground and along inclination extending direction D2 be arranged on the second inclined-plane 116.In addition, the short bar of each magnetoresistive sensor 142 prolongs The extending direction for stretching direction and anisotropic magnetoresistance presss from both sides 45 degree.

The second field sensing unit and third field sensing unit that Fig. 2A is Figure 1A are when sensing the direction y magnetic-field component Equivalent circuit diagram, and the second field sensing unit and third field sensing unit that Fig. 2 B is Figure 1A are in the sensing direction z magnetic field point Equivalent circuit diagram when amount.Please also refer to Figure 1A and Fig. 2A, when exterior magnetic field has the direction+y magnetic-field component, by these magnetic The appropriately configured mode for hindering the direction of magnetization of sensor 132 and 142 and the extending direction of short bar, may make magnetoresistive sensor Resistance generation+Δ R variation of 132a and magnetoresistive sensor 142a, and make magnetoresistive sensor 132b's and magnetoresistive sensor 142b Resistance generation-Δ R variation passes through the switching of switching circuit 150 at this time, endpoint P3 and endpoint P6 may make all to be electrically connected to Endpoint P7, and endpoint P4 and endpoint P5 is made all to be electrically connected to endpoint P8, and make the second field sensing unit 130 and third magnetic Field sensing unit 140 is electrically connected into a kind of wheatstone full-bridge.At this point, endpoint P1 and endpoint P2 are applied voltage difference, so hold Voltage difference can be generated by becoming between point P7 and endpoint P8, and the voltage absolute value of the difference between endpoint P7 and endpoint P8 and the direction y magnetic The absolute value of field component is positively correlated.In this way, which the direction y can be obtained using the voltage difference between endpoint P7 and endpoint P8 The size of magnetic-field component, and the second field sensing unit 130 is made to realize the direction y magnetic field point with third field sensing unit 140 The sensing of amount.

Referring again to Figure 1A and Fig. 2 B, when exterior magnetic field has the direction+z magnetic-field component, magnetoresistive sensor 132b and magnetic The resistance of resistance sensor 142a can generate+the variation of Δ R, and the resistance of magnetoresistive sensor 132a and magnetoresistive sensor 142b can produce The variation of life-Δ R passes through the switching of switching circuit 150 at this time, endpoint P3 and endpoint P5 may make all to be electrically connected to endpoint P7, and endpoint P4 and endpoint P6 is made all to be electrically connected to endpoint P8, and the second field sensing unit 130 is felt with third magnetic field Unit 140 is surveyed to be electrically connected into another wheatstone full-bridge.At this point, endpoint P1 and endpoint P2 are applied voltage difference, such endpoint Voltage difference can be generated by becoming between P7 and endpoint P8, and the voltage absolute value of the difference between endpoint P7 and endpoint P8 and the direction z magnetic field The absolute value of component is positively correlated.In this way, which the direction z magnetic can be obtained using the voltage difference between endpoint P7 and endpoint P8 The size of field component, and the second field sensing unit 130 is made to realize the direction z magnetic-field component with third field sensing unit 140 Sensing.

In the field sensing unit 100 of the present embodiment, due to the second field sensing unit 130 and third sensing magnetic fields list Member 140 can switch to two different wheatstone full-bridges via circuit, to sense second direction (such as the direction y) and third respectively The magnetic-field component in direction (such as the direction z), thus field sensing unit 100 can using less magnetoresistive sensor 122,132, 142 can sense the magnetic-field component in three directions.In this way, which the framework of field sensing unit 100 just can be simplified, and contract The volume of small magnetic field sensing device 100.In addition, second field sensing unit 130 is felt with third magnetic field by switching circuit 150 It surveys unit 140 to switch to respectively to two wheatstone full-bridges for sensing second direction and third direction, can make to correspond to second Direction magnetic-field component is directly exported from the two wheatstone full-bridges with the signal for corresponding to third direction magnetic-field component, and can not It could be obtained with being calculated by counting circuit.Therefore, field sensing unit 100 can have better simply framework, and then reduce Cost of manufacture.

In the present embodiment, field sensing unit 100 further includes the first direction of magnetization assignment component 200 and the second magnetization side To assignment component 300.First direction of magnetization assignment component 200 is configured at by the first field sensing unit 120, and to set The direction of magnetization of these magnetoresistive sensors 122 of one field sensing unit 120.Second direction of magnetization assignment component 300 is configured at Second field sensing unit 130 with by third field sensing unit 140, and to set the second field sensing unit 130 and the The direction of magnetization of these magnetoresistive sensors 132 and 142 of three field sensing units 140.

Specifically, in the present embodiment, the first direction of magnetization assignment component 200 and the second direction of magnetization assignment component 300 respectively include the first helical form conductive unit 210, the second helical form conductive unit 220 and third helical form conductive unit 230, For lifting the first direction of magnetization assignment component 200 below.Second helical form conductive unit 220 is electrically connected at the first helical form and leads Between electric unit 210 and third helical form conductive unit 230, and the second helical form conductive unit 220 extends spirally direction not It is same as the direction that extends spirally of the first helical form conductive unit 210, and the spiral for being different from third helical form conductive unit 230 is prolonged Stretch direction.In the present embodiment, direction is extended spirally for example to be defined as when the first helical form conductive unit 210, the second spiral The flow direction of electric current when shape conductive unit 220 and third helical form conductive unit 230 are connected in series.

Fig. 1 C is please referred to, when electric current is injected from endpoint C1, sequentially flows into the first spiral via conductive segment 240 and endpoint C2 Shape conductive unit 210, and electric current flow to endpoint C3 in the first helical form conductive unit 210 in a counterclockwise direction.Then, electric current Endpoint C4 is flow to from endpoint C3 via conductive segment 250.Then, electric current flows through the second helical form from endpoint C4 in a clockwise direction and leads After electric unit 220, then third helical form conductive unit 230 is flowed through in a counterclockwise direction and flow to endpoint C5.Finally, electric current is from end Point C5 flow to endpoint C6 via conductive segment 260, and flows out from endpoint C6.Therefore, in fig. 1 c, the first helical form conductive unit 210 extend spirally direction be it is counterclockwise, the direction that extends spirally of the second helical form conductive unit 220 is clockwise, and third The direction that extends spirally of helical form conductive unit 230 is counterclockwise.

In the present embodiment, the first helical form conductive unit 210 and the second helical form conductive unit 220 are respectively provided with electric current The conductive segment for flowing to E1, current direction E2 and current direction E3 is to be located at magnetoresistive sensor 122a and magnetoresistive sensor 122b just Top, wherein current direction E1, current direction E2 and current direction E3 are directed towards the direction+x, therefore can be by magnetoresistive sensor 122a It is set as the direction-y with the direction of magnetization of magnetoresistive sensor 122b.In addition, the second helical form conductive unit 220 and third helical form It is to be located at magnetoresistive sensor that conductive unit 230, which is respectively provided with current direction E4, current direction E5 and the conductive segment of current direction E6, The surface of 122c and magnetoresistive sensor 122d, wherein current direction E4, current direction E5 and current direction E6 are directed towards the side-x To, therefore the direction of magnetization of magnetoresistive sensor 122c and magnetoresistive sensor 122d can be set as the direction+y.In this way, when the When one direction of magnetization assignment component 200 is powered, just the direction of magnetization of magnetoresistive sensor 122a~122d can be set to appropriate Initial value, and the magnetic-field component in the direction x can be correctly sensed by making the first field sensing unit 120 next.

In other words, when electric current sequentially flows through the first helical form conductive unit 210, the second helical form conductive unit 220 and When three helical form conductive units 230, belong to these magnetoresistive sensors 122a and 122b of a half-bridge of Wheatstone bridge just on The current direction first direction (such as the direction+x) of side or underface (right above such as), belong to another half-bridge of Wheatstone bridge These magnetoresistive sensors 122c and 122d surface or underface (such as right above) current direction second direction (example Such as the direction-x), wherein first direction (such as the direction+x) is in contrast to second direction (such as the direction-x).

Similarly, the first helical form conductive unit 210 of the second direction of magnetization assignment component 300, the second helical form are conductive single Member 220 and third helical form conductive unit 230 can be configured at the second field sensing unit 130 and third field sensing unit 140 tops.In addition, the first helical form conductive unit 210 of the first direction of magnetization assignment component 200, the second helical form are conductive single Member 220 and third helical form conductive unit 230 are arranged along the direction y, however, the of the second direction of magnetization assignment component 300 One helical form conductive unit 210, the second helical form conductive unit 220 and third helical form conductive unit 230 can be along the side x To arrangement, to be suitble to setting magnetoresistive sensor 132a, magnetoresistive sensor 132b, magnetoresistive sensor 142a, magnetoresistive sensor 142b The direction of magnetization.

In the present embodiment, the first direction of magnetization assignment component 200 and the first field sensing unit 120 can form magnetic field sense Module 400 is surveyed, to measure the direction x magnetic-field component.In addition, the second direction of magnetization assignment component 300, the second field sensing unit 130 and third field sensing unit 140 can form sensing magnetic fields module 500, to measure the direction y magnetic-field component and the direction z magnetic field Component.

In the sensing magnetic fields module 400, sensing magnetic fields module 500 of the present embodiment, due to the second helical form conductive unit 220 direction that extends spirally for extending spirally direction and being different from the first helical form conductive unit 210, and it is different from third helical form Conductive unit 230 extends spirally direction, therefore can use simple three spiral conductive units and can effectively set magnetic Field sensing unit (such as first field sensing unit 120, the second field sensing unit 130, third field sensing unit 140) The direction of magnetization of these magnetoresistive sensors 122,132,142, therefore the sensing magnetic fields module 400 of the present embodiment, sensing magnetic fields mould The framework of block 500 is simple, and volume can be smaller.

In addition, since the framework of the first direction of magnetization assignment component 200 and the second direction of magnetization assignment component 300 is more simple Single, winding length is shorter so that resistance is smaller, therefore identical application voltage, current can be larger so that it is produced Raw magnetic field is stronger.In this way, can be so that sensing magnetic fields module 400, sensing magnetic fields module 500 have biggish sensing model It encloses.

In addition, can be initialized by the first direction of magnetization assignment component 200 and the second direction of magnetization assignment component 300 The direction of magnetization of one field sensing unit 120, the second field sensing unit 130 and third field sensing unit 140 configures, so that First field sensing unit 120, the second field sensing unit 130 and third field sensing unit 140 rushing in strong exterior magnetic field After hitting, it still is able to by normal use.In addition, by the first direction of magnetization assignment component 200 and second direction of magnetization is changed The current direction of assignment component 300, to form the first field sensing unit 120, the second field sensing unit 130 and third magnetic field The different direction of magnetization configurations of sensing unit 140, can measure the first field sensing unit 120, the second field sensing unit 130 and third field sensing unit 140 dynamical system offset (dynamic system offset).By by measuring value Dynamical system offset is deducted, correct magnetic-field component numerical value can be obtained more quickly.Similarly, also deductible low-frequency noise (low frequency noise), so that measured magnetic-field component numerical value is more accurate.

Fig. 3 is the explosive view of the sensing magnetic fields module of another embodiment of the present invention.Referring to figure 3., the magnetic of the present embodiment Field sensing module 400a is similar with the sensing magnetic fields module 400 of Fig. 1 C, and two main differences are as described below.In the present embodiment Sensing magnetic fields module 400a in, the first direction of magnetization assignment component 200a includes multiple first conductive segment 210a, multiple second Conductive segment 220a, multiple first conductive through hole 230a and multiple second conductive through hole 240a.These the first conductive segment 210a configuration In the upside of the first field sensing unit 120 and the side (in the present embodiment be, for example, upside) of downside, and these second are led Electric section 220a is configured at the upside of the first field sensing unit 120 and the other side of downside (under being, for example, in the present embodiment Side).These the first conductive through hole 230a are by these the first conductive segment 210a of part and partial these second conductive segments 220a Connect into the first helical form conductive unit 250a, these the second conductive through hole 240a are by these first conductive segments of another part The second conductive segment of these of 210a and another part 220a connects into the second helical form conductive unit 260a, wherein the first helical form The direction that extends spirally of conductive unit 250a extends spirally direction different from the second helical form conductive unit 260a.

In the present embodiment, can flow through the first conductive segment 211 via the electric current that contact 270a flows into the first conductive segment 211 and It is flow to the first conductive through hole 231, the second conductive segment 221 is then passed through and flow to the first conductive through hole 232.Then, electric current from First conductive through hole 232 flows through the first part 2121 of the first conductive segment 212, and so far, clockwise flowing is presented in electric current, And the first conductive segment 211, the first conductive through hole 231, the second conductive segment 221, the first conductive through hole 232 and the first conductive segment 212 First part 2121 i.e. formed the first helical form conductive unit 250a, and its extend spirally direction for clockwise.

Then, electric current flow to the second part 2122 of the first conductive segment 212 from first part 2121, is then flowing through second Through flowing to the second conductive segment 222 by the second conductive through hole 241 behind part 2122.Later, electric current is from the second conductive segment 222 via Two conductive through holes 242 flow to the first conductive segment 213.Finally, electric current flow to contact 280a from the first conductive segment, and from contact 280a Flow out the first direction of magnetization assignment component 200a.In this way, which electric current is just presented counterclockwise since second part 2122 Flowing, and second part 2122, the second conductive through hole 241, the second conductive segment 222, the second conductive through hole 242 and the first conductive segment 213 just form the second helical form conductive unit 260a, and it extends spirally direction as counterclockwise.

In the present embodiment, the first helical form conductive unit 250a winds magnetoresistive sensor 122a and magnetoresistive sensor 122b, therefore the direction of magnetization of magnetoresistive sensor 122a and magnetoresistive sensor 122b can be set as the direction-y.In addition, the second spiral shell Shape conductive unit 260a winding magnetoresistive sensor 122c and magnetoresistive sensor 122d is revolved, therefore can be by magnetoresistive sensor 122c and magnetic The direction of magnetization of resistance sensor 122d is set as the direction+y.

In the present embodiment, one of these first conductive segments 210a (for example, the first conductive segment 212) is U-shaped conductive segment, A part (i.e. first part 2121) of this U-shaped conductive segment belongs to the first helical form conductive unit 250a, this U-shaped conductive segment it is another A part of (i.e. second part 2122) belongs to the second helical form conductive unit 260a.

In the present embodiment, the second direction of magnetization assignment component can also have such as the first direction of magnetization assignment component 200a Possessed first helical form conductive unit 250a and the second helical form conductive unit 260a, wherein the first helical form conductive unit 250a winds magnetoresistive sensor 132b and magnetoresistive sensor 142b, and the second helical form conductive unit 260a winds magnetoresistive sensor 132a and magnetoresistive sensor 142a, and the first helical form conductive unit 250a and the second helical form conductive unit 260a are along the side-x To arrangement.

In the sensing magnetic fields module 400a of the present embodiment, due to the side of extending spirally of the first helical form conductive unit 250a To the direction that extends spirally different from the second helical form conductive unit 260a, therefore can be using simple multiple first conductive segments 210a, multiple second conductive segment 220a and conductive through hole (such as first conductive through hole 230a and the second conductive through hole 240a) energy These magnetic resistance of enough effectively settings field sensing unit (such as first field sensing unit 120, the second field sensing unit 130) The direction of magnetization of sensor 122,142.So the framework of the sensing magnetic fields module 400a of the present embodiment is simple, and volume can be with It is smaller.In addition, winding length is shorter since the framework of the first direction of magnetization assignment component 200a is relatively simple so that resistance compared with It is small, thus identical application voltage, current can be larger so that its generated magnetic field is stronger.In this way, So that sensing magnetic fields module 400a has biggish sensing range.

In the present embodiment, these the first conductive segment 210a and these second conductive segments 220a partly overlaps.For example, First conductive segment 211 is at the edge of the side (i.e. lower right side in Fig. 3) in the direction+y and the second conductive segment 221 the one of the direction-y The imbricate of side (i.e. upper left side in Fig. 3), and the second conductive segment 221 is at the edge and the first conductive segment of the side in the direction+y Imbricate of 212 first part 2121 in the side in the direction-y.In addition, the second part 2122 of the first conductive segment 212+ The edge of the side in the direction y and the second conductive segment 222 are in the imbricate of the side in the direction-y, and the second conductive segment 222 is in+y The imbricate of the edge of the side in direction and the first conductive segment 213 in the side in the direction-y.As these first conductive segments 210a When partly overlapping with these second conductive segments 220a, under identical electric current, the first helical form conductive unit 250a and the second spiral shell Revolving magnetic field caused by shape conductive unit 260a can be stronger.In this way, can so that the present embodiment sensing magnetic fields module 400a has bigger sensing range.

Fig. 4 is the explosive view of the sensing magnetic fields module of another embodiment of the present invention.Referring to figure 4., the magnetic of the present embodiment Field sensing module 400b is similar with the sensing magnetic fields module 400a of Fig. 3, and two main differences are as described below.In the present embodiment Sensing magnetic fields module 400b in, the first direction of magnetization assignment component 200b includes multiple first conductive segment 211b, 212b, 213b And 214b, multiple second conductive segment 221b, 222b and 223b, multiple first conductive through hole 231b, 232b and 233b and multiple Two conductive through hole 241b, 242b and 243b.

In the present embodiment, the first conductive segment 211b can be flowed through via the electric current that contact 270a flows into the first conductive segment 211b And it is flow to the first conductive through hole 231b, it then passes through the second conductive segment 221b and flow to the first conductive through hole 232b.Then, electric Stream flows through the first conductive segment 212b from the first conductive through hole 232b and flow to the first conductive through hole 233b, then again from the first conduction Perforation 233b flows through the first part 2221b of the second conductive segment 222b.So far, the clockwise flowing of electric current presentation, and the One conductive segment 211b, the first conductive through hole 231b, the second conductive segment 221b, the first conductive through hole 232b, the first conductive segment 212b, The first part 2221b of first conductive through hole 233b and the second conductive segment 222b form the first helical form conductive unit 250b, And it extends spirally direction as clockwise.

Then, electric current flow to the second part 2222b of the second conductive segment 222b from first part 2221b, is then flowing through Through flowing to the first conductive segment 213b by the second conductive through hole 241b after second part 2222b.Then, electric current is via the first conductive segment 213b flow to the second conductive through hole 242b, then flow to the second conduction via the second conductive segment 223b from the second conductive through hole 242b and pass through Hole 243b.Finally, electric current flow to contact 280a via the first conductive segment 214b from the second conductive through hole 243b, and from contact 280a Flow out the first direction of magnetization assignment component 200b.In this way, which side counterclockwise is just presented in electric current since second part 2222b To flowing, and second part 2222b, the second conductive through hole 241b, the first conductive segment 213b, the second conductive through hole 242b, second Conductive segment 223b, the second conductive through hole 243b and the first conductive segment 214b just form the second helical form conductive unit 260b, and its Direction is extended spirally as counterclockwise.

In the present embodiment, the first helical form conductive unit 250b winds magnetoresistive sensor 122a and magnetoresistive sensor 122b, therefore the direction of magnetization of magnetoresistive sensor 122a and magnetoresistive sensor 122b can be set as the direction-y.In addition, the second spiral shell Shape conductive unit 260b winding magnetoresistive sensor 122c and magnetoresistive sensor 122d is revolved, therefore can be by magnetoresistive sensor 122c and magnetic The direction of magnetization of resistance sensor 122d is set as the direction+y.

In the present embodiment, one of these second conductive segments (for example, the second conductive segment 222b) are U-shaped conductive segment, this U A part (i.e. first part 2221b) of shape conductive segment belongs to the first helical form conductive unit 250b, this U-shaped conductive segment it is another Partially (i.e. second part 2222b) belongs to the second helical form conductive unit 260b.It in the present embodiment, is that will be located at the first magnetic field The conductive segment of 120 top of sensing unit is named as the first conductive segment, and will be located at the conduction below the first field sensing unit 120 Section is named as the second conductive segment.In fact, also the conductive segment of 120 lower section of the first field sensing unit can be named as the first conduction The conductive segment of first field sensing unit, 120 top is named as the second conductive segment by section, then U-shaped conductive segment can belong to first Conductive segment.

In the present embodiment, the second direction of magnetization assignment component can also have such as the first direction of magnetization assignment component 200b Possessed first helical form conductive unit 250b and the second helical form conductive unit 260b, wherein the first helical form conductive unit 250b winds magnetoresistive sensor 132b and magnetoresistive sensor 142b, and the second helical form conductive unit 260b winds magnetoresistive sensor 132a and magnetoresistive sensor 142a, and the first helical form conductive unit 250b and the second helical form conductive unit 260b are along the side-x To arrangement.

In the present embodiment, these first conductive segments and these second conductive segments are least partially overlapped, and the area being overlapped It is also bigger than the embodiment of Fig. 3, so that magnetic field generation efficiency is bigger.

Fig. 5 is the explosive view of the sensing magnetic fields module of one more embodiment of the present invention.Referring to figure 5., the magnetic of the present embodiment Field sensing module 400c is similar with the sensing magnetic fields module 400a of Fig. 3, and two main differences are as described below.In the present embodiment Sensing magnetic fields module 400c in, the first direction of magnetization assignment component 200c include multiple first conductive segment 211c, 212c, 213c, 214c and 215c, multiple second conductive segment 221c, 222c, 223c and 224c, multiple first conductive through hole 231c, 232c, 233c and 234c and multiple second conductive through hole 241c, 242c, 243c and 244c.

In the present embodiment, the first conductive segment 211c can be flowed through via the electric current that contact 270a flows into the first conductive segment 211c And it is flow to the first conductive through hole 231c, it then passes through the second conductive segment 221c and flow to the first conductive through hole 232c.Then, electric Stream flows through the first conductive segment 212c from the first conductive through hole 232c and flow to the first conductive through hole 233c, then again from the first conduction Perforation 233c flows through the second conductive segment 222c and flow to the first conductive through hole 234c.Then, electric current is again from the first conductive through hole 234c flows through the first part 2131c of the first conductive segment 213c.So far, clockwise flowing is presented in electric current, and first leads Electric section 211c, the first conductive through hole 231c, the second conductive segment 221c, the first conductive through hole 232c, the first conductive segment 212c, first Conductive through hole 233c, the second conductive segment 222c, the first conductive through hole 234c and the first conductive segment 213c first part 2131c be The first helical form conductive unit 250c is formed, and it extends spirally direction as clockwise.

Then, electric current flow to the second part 2132c of the first conductive segment 213c from first part 2131c, is then flowing through Through flowing to the second conductive segment 223c by the second conductive through hole 241c after second part 2132c.Then, electric current is via the second conductive segment 223c flow to the second conductive through hole 242c, then flow to the second conduction via the first conductive segment 214c from the second conductive through hole 242c and pass through Hole 243c.Then, electric current flow to the second conductive through hole 244c via the second conductive segment 224c from the second conductive through hole 243c.Most Afterwards, electric current flow to contact 280a via the first conductive segment 215c from the second conductive through hole 244c, and flows out first from contact 280a Direction of magnetization assignment component 200c.In this way, electric current, which is just presented, counterclockwise to be flowed since second part 2132c, and Second part 2132c, the second conductive through hole 241c, the second conductive segment 223c, the second conductive through hole 242c, the first conductive segment 214c, the second conductive through hole 243c, the second conductive segment 224c, the second conductive through hole 244c and the first conductive segment 215c just form Two helical form conductive unit 260c, and it extends spirally direction as counterclockwise.

In the present embodiment, the first helical form conductive unit 250c winds magnetoresistive sensor 122a and magnetoresistive sensor 122b, therefore the direction of magnetization of magnetoresistive sensor 122a and magnetoresistive sensor 122b can be set as the direction-y.In addition, the second spiral shell Shape conductive unit 260c winding magnetoresistive sensor 122c and magnetoresistive sensor 122d is revolved, therefore can be by magnetoresistive sensor 122c and magnetic The direction of magnetization of resistance sensor 122d is set as the direction+y.

In the present embodiment, one of these first conductive segments (for example, the first conductive segment 213c) are U-shaped conductive segment, this U A part (i.e. first part 2131c) of shape conductive segment belongs to the first helical form conductive unit 250c, this U-shaped conductive segment it is another Partially (i.e. second part 2132c) belongs to the second helical form conductive unit 260c.

In the present embodiment, the second direction of magnetization assignment component can also have such as the first direction of magnetization assignment component 200c Possessed first helical form conductive unit 250c and the second helical form conductive unit 260c, wherein the first helical form conductive unit 250c winds magnetoresistive sensor 132b and magnetoresistive sensor 142b, and the second helical form conductive unit 260c winds magnetoresistive sensor 132a and magnetoresistive sensor 142a, and the first helical form conductive unit 250c and the second helical form conductive unit 260c are along the side-x To arrangement.

In the present embodiment, these first conductive segments and these second conductive segments are least partially overlapped, and the area being overlapped It is also bigger than the embodiment of Fig. 3, so that magnetic field generation efficiency is bigger.

In conclusion in the field sensing unit of the embodiment of the present invention, due to the second field sensing unit and third Field sensing unit can switch to two different wheatstone full-bridges via circuit, to sense second direction and third direction respectively Magnetic-field component, therefore field sensing unit can sense the magnetic field point in three directions using less magnetoresistive sensor Amount.In this way, which the framework of field sensing unit just can be simplified, and reduce the volume of field sensing unit.Of the invention In the sensing magnetic fields module of embodiment, since the direction that extends spirally of the second helical form conductive unit is led different from the first helical form Electric unit extends spirally direction, and extends spirally direction different from third helical form conductive unit, therefore can use letter Three single spiral conductive units can effectively set the direction of magnetization of these magnetoresistive sensors of field sensing unit, therefore The framework of the sensing magnetic fields module of the embodiment of the present invention is simple, and volume can be smaller.In the magnetic field of the embodiment of the present invention In sensing module, due to the spiral for extending spirally direction and being different from the second helical form conductive unit of the first helical form conductive unit Extending direction, therefore can be using simply multiple first conductive segments, multiple second conductive segments and conductive through hole can be effective Set the direction of magnetization of these magnetoresistive sensors of field sensing unit.So the sensing magnetic fields module of the embodiment of the present invention Framework it is simple, and volume can be smaller.

Although the present invention is disclosed as above with embodiment, however, it is not to limit the invention, any technical field Middle those of ordinary skill, it is without departing from the spirit and scope of the present invention, therefore of the invention when can make a little change and retouching Protection scope is subject to view appended claims confining spectrum.

Claims (7)

1. a kind of sensing magnetic fields module characterized by comprising

Field sensing unit, including multiple magnetoresistive sensors for connecting into Wheatstone bridge, and the magnetic field to sense a direction Component；And

Direction of magnetization assignment component is configured at by the field sensing unit, and the institute to set the field sensing unit The direction of magnetization of multiple magnetoresistive sensors is stated, the direction of magnetization assignment component includes:

First helical form conductive unit；

Second helical form conductive unit；And

Third helical form conductive unit, wherein the second helical form conductive unit is electrically connected at the first helical form conduction Between unit and the third helical form conductive unit, and the direction that extends spirally of the second helical form conductive unit is different from The first helical form conductive unit extends spirally direction, and is different from extending spirally for the third helical form conductive unit Direction.

2. sensing magnetic fields module according to claim 1, which is characterized in that the multiple magnetoresistive sensor is anisotropy Magnetoresistive sensor.

3. sensing magnetic fields module according to claim 1, which is characterized in that when electric current sequentially flows through first helical form When conductive unit, the second helical form conductive unit and the third helical form conductive unit, belong to the Wheatstone bridge A half-bridge the multiple magnetoresistive sensor surface or underface current direction first direction, belong to the wheatstone The surface of the multiple magnetoresistive sensor of another half-bridge of electric bridge or the current direction second direction of underface, wherein described First direction is in contrast to the second direction.

4. a kind of sensing magnetic fields module characterized by comprising

Field sensing unit, including multiple magnetoresistive sensors for connecting into Wheatstone bridge, and the magnetic field to sense a direction Component；And

Direction of magnetization assignment component is configured at by the field sensing unit, and the institute to set the field sensing unit The direction of magnetization of multiple magnetoresistive sensors is stated, the direction of magnetization assignment component includes:

Multiple first conductive segments, are configured at the upside of the field sensing unit and the side of downside；

Multiple second conductive segments, are configured at the upside of the field sensing unit and the other side of downside；

Multiple first conductive through holes connect the multiple first conductive segment of part and partial the multiple second conductive segment At the first helical form conductive unit；And

Multiple second conductive through holes are led the multiple the second of the multiple first conductive segment of another part and another part Electric section connects into the second helical form conductive unit, wherein the first helical form conductive unit extends spirally direction different from institute That states the second helical form conductive unit extends spirally direction.

5. sensing magnetic fields module according to claim 4, which is characterized in that one of the multiple first conductive segment is U-shaped Conductive segment, a part of the U-shaped conductive segment belongs to the first helical form conductive unit, and the U-shaped conductive segment is another Partly belong to the second helical form conductive unit.

6. sensing magnetic fields module according to claim 4, which is characterized in that the multiple first conductive segment with it is the multiple Second conductive segment partly overlaps.

7. sensing magnetic fields module according to claim 4, which is characterized in that the multiple magnetoresistive sensor is anisotropy Magnetoresistive sensor.