CN202599967U - Magneto-resistor gear sensor - Google Patents

Abstract

The utility model discloses a magneto-resistor gear sensor, which comprises a magnetic sensor chip (181) and a permanent magnet (182), wherein the magnetic sensor chip (181) comprises at least one electrical bridge, and each bridge arm of the electrical bridge comprises at least one MTJ (Magnetic Tunnel Junction) component set. The magneto-resistor gear sensor has the advantages of better temperature stability, higher sensitivity, lower power consumption, better linearity, wider linear working region, and simpler structure. The magneto-resistor gear sensor is provided with a concave soft magnet which ensures that an outer magnetic field generated by the permanent magnet is reduced in component along the sensitive direction of the MTJ component, therefore the MTJ component in the magnetic sensor chip works in a linear working region. The magneto-resistor gear sensor is difficult in being interfered by an interference magnetic field outside the outer magnetic field generated by the permanent magnet. The magneto-resistor gear sensor can ensure a position of some tooth in the gear, when the gear is lack of teeth, the position of the missing tooth can be determined; and the magneto-resistor gear sensor can determine the movement speed of the gear, and can also determine the movement direction of the gear.

Description

A kind of magneto-resistor gear sensor

Technical field

The utility model relates to the gear sensor technical field, and particularly a kind of is the magneto-resistor gear sensor of sensitive element with the MTJ element.

Background technology

Gear sensor is mainly used in the automation control system, with the rotating speed and the rotation direction of prototype gear.At present, gear sensor commonly used is light sensor and Magnetic Sensor.In the mechanical rotation system, in the face of rugged surroundings such as vibrations, impact, greasy dirts, Magnetic Sensor has bigger advantage than light sensor.Many dissimilar Magnetic Sensors are arranged in the prior art, are the Magnetic Sensor of sensitive element with Hall (Hall) element, anisotropic magnetoresistance (AMR) element or giant magnetoresistance (GMR) element for example.

The Magnetic Sensor sensitivity that with the Hall element is sensitive element is very low, needs to use the magnetism gathering rings structure amplify magnetic field usually, and to improve the sensitivity of Hall element, this has increased with the Hall element is the volume and weight of the sensor of sensitive element.In addition, be that the sensor of sensitive element has that power consumption is big, the defective of poor linearity with the Hall element.The remolding sensitivity Hall element of AMR element is high a lot, but the linear work district of AMR element is narrow.With the AMR element is that the Magnetic Sensor of sensitive element needs to be provided with " set/reset " coil it is preset-reset operation; This not only causes with the AMR element is that the manufacturing process of Magnetic Sensor of sensitive element is complicated, and to make with the AMR element be that the size and the power consumption of the Magnetic Sensor of sensitive element all increases.With the GMR element is that the Magnetic Sensor of sensitive element is that the sensor of sensitive element has higher sensitivity with the Hall element, but is that the linear work district of Magnetic Sensor of sensitive element is narrow partially with the GMR element.Therefore in addition, the response curve of GMR element is even symmetry, is that the Magnetic Sensor of sensitive element can only be measured unipolar gradient magnetic with the GMR element, not the ambipolar gradient magnetic of energy measurement.

In recent years, a kind of novel magnetoresistance effect sensor is that the Magnetic Sensor of sensitive element begins in industry, to use with magnetic tunnel-junction (MTJ, Magnetic Tunnel Junction) element promptly.With the MTJ element is that the principle of work of the Magnetic Sensor of sensitive element is to utilize the tunnel magneto resistance of magnetoresistance effect material (TMR, Tunnel Magnetoresistance) effect that magnetic field is responded to.AMR element and GMR element that the MTJ element is used before have bigger resistance change rate.Compare with Hall element, the MTJ element has better temperature stability, higher sensitivity, the lower power consumption and the better linearity, and does not need extra magnetism gathering rings structure.Compare with the AMR element, the MTJ element has better temperature stability, higher sensitivity and wideer linear work district, and does not need extra " set/reset " loop construction.Compare with the GMR element, the MTJ element has better temperature stability, higher sensitivity, lower power consumption and wideer linear work district.

What common Magnetic Sensor as the gear sensing adopted is printed circuit board (PCB) (PCB) formula structure.PCB formula gear sensor is made up of magnetic sensing chip, peripheral circuit and permanent magnet usually.The external magnetic field H by the permanent magnet generation of its place physical locations of magnetic sensing chip induction _ApplyVariation and output induced signal, peripheral circuit is handled and is changed the induced signal of magnetic sensing chip output.The external magnetic field H by the permanent magnet generation of magnetic sensing chip place physical locations _ApplyVariation very a little less than.Therefore, in the application of PCB formula gear sensor, can prevent to remove the external magnetic field H that permanent magnet produces _ApplyOutside the interference of disturbing magnetic field become the technical matters that needs to be resolved hurrily.

Though the MTJ element has high sensitivity, be that the Magnetic Sensor of sensitive element still exists following deficiency with the MTJ element:

(1) the external magnetic field H of permanent magnet generation _ApplyComponent along MTJ element sensitive direction is very big, causes the MTJ element to descend because of departing from its linear work district performance, even causes the MTJ element can't work because of reaching capacity;

(2) the external magnetic field H by the permanent magnet generation of its place physical locations of magnetic sensing chip induction _ApplyVariation the time, receive the external magnetic field H that produces except that permanent magnet easily _ApplyOutside the interference of disturbing magnetic field;

(3) be not sure of the position of certain tooth in the gear, when the gear hypodontia, can not confirm the particular location of hypodontia;

(4) can't confirm the direction of motion of gear;

(5) be difficult to realize large-scale production cheaply.

Therefore, the gear sensor that needs a kind of accurately sensing gear movement state.

The utility model content

The purpose of the utility model provides a kind of magneto-resistor gear sensor.

Magneto-resistor gear sensor according to the utility model comprises the magnetic sensing chip and first permanent magnet, and said magnetic sensing chip comprises at least one electric bridge, and each brachium pontis of this electric bridge comprises at least one MTJ element group.

Preferably, said sensor further comprises the soft magnetic bodies that is arranged at the spill between said magnetic sensing chip and said first permanent magnet, and the opening of said soft magnetic bodies is towards said magnetic sensing chip.

Preferably, said at least one MTJ element group is a plurality of MTJ element groups, and these a plurality of MTJ element groups are connected and/or are connected in parallel.

Preferably, these a plurality of MTJ element groups are connected and/or are connected in parallel with same sensitive direction.

Preferably, each comprises that the brachium pontis of MTJ element group has identical sensitive direction.

Preferably, said electric bridge is half-bridge, full-bridge or the bridge of enjoying a double blessing.

Preferably, each MTJ element group comprises series connection and/or a plurality of MTJ elements that are connected in parallel.

Preferably, each MTJ element group comprises a plurality of MTJ elements of connecting and/or being connected in parallel with same sensitive direction.

Preferably, each MTJ element is a multi-layer film structure, comprises pinning layer, nailed layer, tunnel barrier layer and the magnetic free layer of deposition successively.

Preferably, the both sides of said each MTJ element group are provided with a pair of second permanent magnet, and this is obliquely installed with respect to the sensitive direction of this MTJ element group second permanent magnet and is used for bias magnetic field to said MTJ element group being provided.

Preferably, the both sides of said each MTJ element group are provided with a pair of second permanent magnet, and this is obliquely installed the nile coupled field that is used to eliminate said MTJ element group to second permanent magnet with respect to the sensitive direction of this MTJ element group.

Preferably, this is obliquely installed the nile coupled field that is further used for eliminating said MTJ element group to second permanent magnet with respect to the sensitive direction of this MTJ element group.

Preferably, each MTJ element is a multi-layer film structure, comprises pinning layer, nailed layer, tunnel barrier layer, magnetic free layer and the biasing layer of deposition successively.

Preferably, each MTJ element further comprises the separation layer of being located between said magnetic free layer and the said biasing layer.

Preferably, said sensor further comprises the control circuit that is electrically connected with said magnetic sensing chip.

Preferably, said control circuit is confirmed the position of the gear teeth according to the corresponding relation of the voltage signal of said magnetic sensing chip output and gear tooth location point.

Preferably, said magnetic sensing chip comprises the bridge of enjoying a double blessing, and each brachium pontis of the said bridge of enjoying a double blessing comprises MTJ element group, and said control circuit is confirmed the direction of motion of gear according to the voltage signal of said magnetic sensing chip output.

Preferably, said sensor further comprises shell.

The utlity model has following beneficial effect:

(1) said sensor is a sensitive element with the MTJ element; Compare with the sensor that with Hall element, AMR element or GMR element is sensitive element, the temperature stability of said sensor is better, sensitivity is higher, power consumption is lower, the linearity is better, the linear work district is wideer, structure is simpler;

(2) said sensor is provided with the soft magnetic bodies of spill, external magnetic field that permanent magnet produces is reduced along the component of MTJ element sensitive direction, thereby guarantee that the MTJ element in the magnetic sensing chip is operated in its linear work district, make said sensor performance be improved significantly;

(3) the magnetic sensing chip of said sensor adopts full-bridge, makes said sensor be not easy to receive the interference of the disturbing magnetic field the external magnetic field that produces except that said permanent magnet;

(4) in a kind of preferred embodiment, the both sides of MTJ element are provided with the permanent magnet of pair of angled, and the magnetic field that the permanent magnet of this inclination produces provides bias magnetic field perpendicular to the component of MTJ element sensitive direction for the MTJ element.Can adjust the saturation field of MTJ element through changing this bias magnetic field, thereby obtain to have highly sensitive sensor, or can realize the sensor of different sensitivity as required;

(5) in a kind of preferred embodiment; The both sides of MTJ element are provided with the permanent magnet of pair of angled; The nile coupled field of MTJ element can be eliminated in the magnetic field that the permanent magnet of this inclination produces along the component of MTJ element sensitive direction; Thereby the working point that guarantees the MTJ element is in its linear work district, has improved the linearity of said sensor;

(6) in another kind of preferred embodiment, the magnetic free layer of MTJ element is provided with the biasing layer, and this biasing layer can provide the bias magnetic field perpendicular to MTJ element sensitive direction for the magnetic free layer.Can adjust the saturation field of MTJ element through changing this bias magnetic field, thereby obtain to have highly sensitive sensor, or can realize the sensor of different sensitivity as required;

(7) said sensor can be confirmed the position of certain tooth in the gear, when the gear hypodontia, can also confirm the position of hypodontia;

(8) said sensor not only can be confirmed the movement velocity of gear, and can confirm the direction of motion of gear;

(9) said sensor both had been applicable to the linear gear, also was applicable to circular gear;

(10) said sensor helps realizing large-scale production cheaply.

Description of drawings

The structural representation of the MTJ element 11 that Fig. 1 provides for the utility model embodiment 1;

Fig. 2 is the external magnetic field H of the resistance of a MTJ element 11 under the perfect condition _ApplyResponse curve, external magnetic field H _ApplySensitive direction along a MTJ element 11;

Fig. 3 is the external magnetic field H of resistance of a MTJ element 11 in the practical application _ApplyResponse curve, external magnetic field H _ApplySensitive direction along a MTJ element 11;

Fig. 4 is connected into the synoptic diagram of one the one MTJ element group 13 for a plurality of MTJ elements 11;

Fig. 5 is for being provided with the synoptic diagram of pair of angled permanent magnet 14 in a MTJ element group 13 both sides;

Fig. 6 is the sectional view of its Distribution of Magnetic Field on every side after a MTJ element group 13 both sides are provided with the pair of angled permanent magnet;

Fig. 7 is for being provided with the vertical view of pair of angled permanent magnet 14 in a MTJ element group 13 both sides;

Fig. 8 is the vertical view of the physical location of half-bridge 15;

Fig. 9 is the equivalent circuit diagram of half-bridge 15 shown in Figure 8;

Figure 10 is the vertical view of the physical location of full-bridge 16;

Figure 11 is the equivalent circuit diagram of full-bridge 16 shown in Figure 10;

Figure 12 is the curve map of the output voltage of the magnetic field sensor of the employing full-bridge 16 of actual measurement;

Figure 13 is the vertical view of physical location of bridge 17 of enjoying a double blessing;

Figure 14 is the equivalent circuit diagram of the bridge 17 of enjoying a double blessing shown in Figure 13;

The structural representation of the magneto-resistor gear sensor 18 that Figure 15 provides for the utility model embodiment 1;

The synoptic diagram of the sine-shaped voltage signal of magneto-resistor gear sensor 18 outputs that Figure 16 provides for the utility model embodiment 1;

The synoptic diagram of the sinusoidal waveform that Figure 17 exports for the utility model embodiment 1 provides when the gear hypodontia magneto-resistor gear sensor 18 and the voltage signal of square waveform;

The synoptic diagram of the two-way voltage signal of magneto-resistor gear sensor 18 outputs that Figure 18 provides for the utility model embodiment 1;

The structural representation of the 2nd MTJ element 21 that Figure 19 provides for the utility model embodiment 2.

Embodiment

Below in conjunction with accompanying drawing and embodiment the utility model content of the utility model is done further to describe.

Embodiment 1:

The structural representation of the MTJ element 11 that Fig. 1 provides for present embodiment.A said MTJ element 11 is multi-layer film structure, and is as shown in Figure 1, and it comprises insulation course 112, bottom electrode layer 113, pinning layer 114, nailed layer 115, tunnel barrier layer 116, magnetic free layer 117 and the top electrode layer 118 that is deposited on successively on the substrate 111.Said nailed layer 115 is a ferromagnetic layer with said magnetic free layer 117, and its material for example comprises Fe, Co, Ni, FeCo, FeNi, FeCoB or FeCoNi.Said nailed layer 115 also can be the composite bed that ferromagnetic layer, Ru layer and ferromagnetic layer form, for example the composite bed of FeCo layer, Ru layer and the formation of FeCo layer.Exchange-coupling interaction between said pinning layer 114 and the said nailed layer 115 makes the magnetic moment direction 1151 of said nailed layer 115 be pinned at a direction, and outside magnetic field H _ApplyEffect said magnetic moment direction 1151 down remains unchanged.Said pinning layer 114 is an inverse ferric magnetosphere, and its material for example comprises PtMn, IrMn or FeMn.The material of said tunnel barrier layer 116 for example comprises MgO or Al ₂O ₃The magnetic moment direction 1171 of said magnetic free layer 117 can be with external magnetic field H _ApplyChange and change.Outside magnetic field H _ApplyEffect under, the magnetic moment direction 1171 of said magnetic free layer 117 can be from progressively changing into the magnetic moment direction 1151 antiparallel directions with said nailed layer 115 with the magnetic moment direction 1151 parallel directions of said nailed layer 115, and vice versa.In the present embodiment, the magnetic moment direction 1171 of said magnetic free layer 117 is defined as the sensitive direction of a said MTJ element 11.Said top electrode layer 118 adopts non-magnetic conductive material usually with said bottom electrode layer 113.The material of said substrate 111 adopts silicon, quartz, pyroceram, GaAs or AlTiC usually.The area of said insulation course 112 is greater than the area of said bottom electrode layer 113.Said top electrode layer 118 is used for being electrically connected with other element with said bottom electrode layer 113.In the present embodiment, said top electrode layer 118 electrically connects with for example ohmmeter 12 with said bottom electrode layer 113, to measure the resistance of a said MTJ element 11.

The resistance sizes of a said MTJ element 11 is relevant with the relative orientation of the magnetic moment of said magnetic free layer 117 and said nailed layer 115.When the magnetic moment direction of the magnetic moment direction 1171 of said magnetic free layer 117 and said nailed layer 115 1151 was parallel, the resistance value of a said MTJ element 11 was minimum, is called a said MTJ element 11 and is in low resistance state; When magnetic moment direction 1151 antiparallels of the magnetic moment direction of said magnetic free layer 117 1171 and said nailed layer 115, the resistance value of a said MTJ element 11 is maximum, is called a said MTJ element 11 and is in high-impedance state.Utilize resistance value that prior art can realize a said MTJ element 11 along with external magnetic field H _ApplyChange linear change between high-impedance state and low resistance state.

Under perfect condition, the external magnetic field H of the resistance of a said MTJ element 11 _ApplyResponse curve as shown in Figure 2, external magnetic field H _ApplySensitive direction along a said MTJ element 11.When a said MTJ element 11 was in low resistance state or high-impedance state, its response curve reached capacity.Resistance value when a said MTJ element 11 is in low resistance state is marked as for example R _LResistance value when a said MTJ element 11 is in high-impedance state is marked as for example R _HBetween high-impedance state and low resistance state, the resistance value R of a said MTJ element 11 is with external magnetic field H _ApplyChange be linear change.The external magnetic field H of the resistance value R of a said MTJ element 11 _ApplyThe slope of response curve, the resistance value R of a promptly said MTJ element 11 is with external magnetic field H _ApplyRate of change be defined as the sensitivity of a said MTJ element 11.As shown in Figure 2, the external magnetic field H of the resistance of a said MTJ element 11 _ApplyResponse curve be not about H _Apply=0 straight line becomes rotational symmetry, but about H _Apply=H _OStraight line become rotational symmetry.H _OBe commonly called Nai Er coupling (Neel Coupling) field.Generally, Nai Er coupled field H _OSpan be 1-40Oe.

In the linear zone of response curve as shown in Figure 2, the resistance value R of a said MTJ element 11 can approximate representation be:

$R=\frac{R_H-R_L}{2H_s}(H-H_o)+\frac{R_H+R_L}{2},---\left(1\right)$

In the formula (1), H _SThe expression saturation field.Saturation field H _SBe defined as: as Nai Er coupled field H _O=0 o'clock, the external magnetic field H of the resistance of a said MTJ element 11 _ApplyThe tangent line external magnetic field value corresponding of the range of linearity of response curve with the intersection point of the tangent line of forward or negative sense saturation curve.Under perfect condition, the resistance value R of a said MTJ element 11 is with external magnetic field H _ApplyVariation be perfect linear relationship, and do not have magnetic hysteresis.Under actual conditions, because a said MTJ element 11 has hysteresis, the external magnetic field H of the resistance of a said MTJ element 11 _ApplyResponse curve be a curve, as shown in Figure 3.In the sensor application field of reality, since the restriction of magnetic sensing design and the defective of material, the external magnetic field H of the resistance of a said MTJ element 11 _ApplyResponse curve can be more crooked.

In the application, can and/or be connected in parallel into one the one MTJ element group with 11 series connection of an a plurality of MTJ element.In the present embodiment, a MTJ element group 13 is connected in series by for example six the one MTJ elements 11 and forms, and is as shown in Figure 4, and the sensitive direction 1171 of six the one MTJ elements 11 of a MTJ element group 13 is identical.A said MTJ element group 13 is electrically connected with the for example said ohmmeter 12 of other element.When electric current 131 flow through a said MTJ element group 13, the direction of said electric current 131 was as shown in Figure 4.Generally, the direction of said electric current 131 does not exert an influence to the resistance value of MTJ element group 13.Can adjust the resistance value of a said MTJ element group 13 through the number that changes a MTJ element 11 in the MTJ element group 13.Can the brachium pontis of a said MTJ element group 13 as electric bridge also can be used as an a plurality of said MTJ element group 13 of series connection and/or parallel connection a brachium pontis of electric bridge.

In order bias magnetic field H to be provided for a said MTJ element 11 or a said MTJ element group 13 _Cross, and eliminate its nile coupled field H _O, the permanent magnet 14 of pair of angled can be set in the both sides of a said MTJ element 11 or a said MTJ element group 13.In the present embodiment, as shown in Figure 5, be provided with a pair of permanent magnet 14 in the for example both sides of a said MTJ element group 13, and said permanent magnet 14 is placed with respect to sensitive direction 1171 inclinations of a said MTJ element group 13.After magnetizing for said permanent magnet 14, the Distribution of Magnetic Field around the said MTJ element group 13 is as shown in Figure 6.In the present embodiment, the shape of said permanent magnet 14 for example is a rectangular parallelepiped.As shown in Figure 7, the complementary angle of the angle between the sensitive direction 1171 of the long limit of said permanent magnet 14 and a said MTJ element group 13 is defined as the tiltangle of said permanent magnet 14 _SnsThe length of each permanent magnet 14, width and thickness are respectively L, W and t, and the gap between two said permanent magnets 14 is G.

The magnetic field H of the interstitial site of two said permanent magnets 14 _MagBe considered to that the magnetic charge at two said permanent magnet 14 edges produces, and said magnetic field H _MagRelevant with the shape and the boundary condition of said permanent magnet 14.As shown in Figure 7, the remanent magnetism M of said permanent magnet 14 _r141 and the sensitive direction 1171 of a said MTJ element group 13 between angle be defined as the remanent magnetism M of said permanent magnet 14 _r141 tiltangle _MagThe magnetic charge density p at said permanent magnet 14 edges _sRemanent magnetism M with said permanent magnet 14 _rThe remanent magnetism M of 141 size, said permanent magnet 14 _r141 tiltangle _MagTiltangle with said permanent magnet 14 _SnsRelevant.The magnetic charge density p at said permanent magnet 14 edges _sCan be expressed as:

ρ _s=M _rcos(θ _mag+θ _sns) (2)

The magnetic field H that the magnetic charge at said permanent magnet 14 edges produces _MagCan be expressed as:

${\stackrel{\→}{H}}_{\mathrm{mag}}\left(\stackrel{\→}{r}\right)=4\mathrm{\π}\underset{\mathrm{Surface}}{\∫}\frac{{\mathrm{\ρ}}_s}{{(\stackrel{\→}{r}-{\stackrel{\→}{r}}^{\′})}^2}d{S}^{\′}---\left(3\right)$

Magnetic field H as shown in Figure 7, that the magnetic charge at said permanent magnet 14 edges produces _MagThe edge is defined as bias magnetic field H perpendicular to the component of the sensitive direction 1171 of a said MTJ element group 13 _CrossWork as θ _Mag=θ _SnsDuring=pi/2, said bias magnetic field H _CrossCan be expressed as:

$H_{\mathrm{cross}}=-8M_r(a\tan \left(\frac{\mathrm{Lt}}{(\frac{W}{2}-\frac{G}{2})\sqrt{L^2{t}^2{(\frac{W}{2}-\frac{G}{2})}^2}}\right)+a\tan \left(\frac{\mathrm{Lt}}{(\frac{W}{2}+\frac{G}{2})\sqrt{L^2{t}^2{(\frac{W}{2}+\frac{G}{2})}^2}}\right))---\left(4\right)$

Can find out the shape through adjusting two said permanent magnets 14, size, clearance G and remanent magnetism M between the two by formula (4) _r141 size can change the said bias magnetic field H of a said MTJ element group 13 positions _CrossThrough changing said bias magnetic field H _CrossCan adjust the saturation field of a said MTJ element group 13, and then confirm the sensitivity of a said MTJ element group 13.

Said bias magnetic field H _CrossAlso can be expressed as:

H _cross=H _mag·sinθ _mag (5)

The magnetic field H that the magnetic charge at said permanent magnet 14 edges produces _MagThe component H of the sensitive direction 1171 of the said MTJ element group 13 in edge _OffCan be expressed as:

H _ofr=H _mag·cosθ _mag (6)

Can find out by formula (6), through shape, size and the remanent magnetism M that adjusts said permanent magnet 14 _r141 tiltangle _Mag, can change the magnetic field H that the magnetic charge at said permanent magnet 14 edges produces _MagThe component H of the sensitive direction 1171 of the said MTJ element group 13 in edge _Off, to eliminate the nile coupled field H of a said MTJ element 11 itself _O, guarantee that the working point of a said MTJ element 11 is in its linear work district.

Fig. 8 is the vertical view of the physical location of half-bridge 15 at X-Y plane.Fig. 9 is the equivalent circuit diagram of said half-bridge 15.Said half-bridge 15 comprises two brachium pontis 151 and 152, and these two brachium pontis all adopt for example said MTJ element group 13, and the resistance value of these two brachium pontis for example is respectively R1 and R2.The sensitive direction of brachium pontis 151 and brachium pontis 152 is all along sensitive direction 1171.Apply the external magnetic field H that a magnetic field intensity changes in gradient along sensitive direction 1171 _Apply, as shown in Figure 8, the external magnetic field H of the physical locations at said brachium pontis 151 places _ApplyThe external magnetic field H of physical locations at magnetic field intensity and said brachium pontis 152 places _ApplyMagnetic field intensity different.The both sides of said brachium pontis 151 and said brachium pontis 152 all are provided with the permanent magnet 14 of pair of angled.Two input ends of said half-bridge 16 for example are IN1 and IN2, for example said input end IN2 ground connection.The output terminal of said half-bridge 16 for example is OUT1.Between said input end IN1 and said input end IN2, apply steady voltage V _Bias, the variation size of the resistance value R1 of said brachium pontis 151 varies in size with the variation of the resistance value R2 of said brachium pontis 152, and therefore said output terminal OUT1 is with output voltage signal V _OUT1=V ₁

Figure 10 is the vertical view of the physical location of full-bridge 16.Figure 11 is the equivalent circuit diagram of said full-bridge 16.Said full-bridge 16 comprises four brachium pontis 161,162,163 and 164, and these four brachium pontis all adopt a MTJ element group 13 of for example two series connection, and the resistance value of these four brachium pontis for example is respectively R3, R4, R5 and R6.The sensitive direction of brachium pontis 161, brachium pontis 162, brachium pontis 163 and brachium pontis 164 is all along said sensitive direction 1171.Apply the external magnetic field H that a magnetic field intensity changes in gradient along said sensitive direction 1171 _ApplyShown in figure 10, the external magnetic field H of the brachium pontis 161 and the physical locations at brachium pontis 162 places _ApplyMagnetic field intensity and brachium pontis 163 and the external magnetic field H of the physical locations at brachium pontis 164 places _ApplyMagnetic field intensity different.The both sides of each brachium pontis 161, brachium pontis 162, brachium pontis 163 and brachium pontis 164 are respectively arranged with the permanent magnet 14 of pair of angled.Two input ends of said full-bridge 16 for example are respectively IN3 and IN4, for example input end IN4 ground connection.Two output terminals of said full-bridge 16 for example are respectively OUT2 and OUT3.Between said input end IN3 and said input end IN4, apply steady voltage V _BiasThe variation size of the resistance value R4 of the resistance value R3 of brachium pontis 161 or brachium pontis 162 varies in size with the variation of the resistance value R6 of the resistance value R5 of said brachium pontis 163 or said brachium pontis 164; Therefore; Said output terminal OUT2 and said output terminal OUT3 will distinguish output voltage V 2 and V3, and the voltage signal of said full-bridge 16 outputs is V _OUT2=(V3-V2).

In the ideal case, the voltage signal V of said full-bridge 16 outputs _OUT2To the common mode magnetic field H _CMNot response, but to the differential mode magnetic field H _DMResponse is arranged.In the common mode magnetic field H _CMEffect under, said brachium pontis 161, said brachium pontis 162, said brachium pontis 163 are identical with the resistance change of said brachium pontis 164, therefore said full-bridge 16 output voltage signal not.In the ideal case, the resistance value of four brachium pontis of said full-bridge 16 all equals R, i.e. the sensitivity of four brachium pontis of R3=R4=R5=R6=R, and said full-bridge 16 all equals S _R, i.e. S _R3=S _R4=S _R5=S _R6=S _R, then have:

$V_2=-\frac{S_{R4}\·H_{\mathrm{dM}}}{2R_4}{V}_{\mathrm{bias}}=-\frac{S_R{H}_{\mathrm{dM}}}{2R}{V}_{\mathrm{bias}},---\left(7\right)$

$V_3=(\frac{R_6+S_{R6}{H}_{\mathrm{dM}}}{R_6+S_{R6}{H}_{\mathrm{dM}}+R_5-S_{R5}{H}_{\mathrm{dM}}}-\frac{R_6}{R_5+R_6})V_{\mathrm{bias}}=\frac{S_{R6}{H}_{\mathrm{dM}}}{R_5+R_6}{V}_{\mathrm{bias}}=\frac{S_R{H}_{\mathrm{dM}}}{2R}{V}_{\mathrm{bias}},---\left(8\right)$

$V_{\mathrm{OUT}2}=V_3-V_2=\frac{S_R{H}_{\mathrm{dM}}}{R}{V}_{\mathrm{bias}},---\left(9\right)$

Can find out by formula (9), the voltage signal of said full-bridge 16 outputs only with the differential mode magnetic field H _DMRelevant, and with the common mode magnetic field H _CMIrrelevant.Therefore, said full-bridge 16 has the ability of very strong inhibition common mode magnetic interference.The typical case of said full-bridge 16 exports shown in figure 12.

In practical application, sensor also can adopt two full-bridges, the bridge of promptly enjoying a double blessing.Figure 13 is the vertical view of physical location of bridge 17 of enjoying a double blessing.Figure 14 is the equivalent circuit diagram of the said bridge 17 of enjoying a double blessing.The said bridge 17 of enjoying a double blessing comprises eight brachium pontis 171,172,173,174,175,176,177 and 178; These eight brachium pontis all adopt a said MTJ element group 13 of for example three parallel connections, and the resistance value of these eight brachium pontis for example is respectively R7, R8, R9, R10, R11, R12, R13 and R14.Shown in figure 14, for example brachium pontis 171, brachium pontis 172, brachium pontis 173 and brachium pontis 174 constitute a full-bridge, and brachium pontis 175, brachium pontis 176, brachium pontis 177 and brachium pontis 178 constitute a full-bridge.Preferably, the sensitive direction of eight brachium pontis of the said bridge 17 of enjoying a double blessing is all along sensitive direction 1171.Apply the external magnetic field H that a magnetic field intensity changes in gradient along sensitive direction 1171 _ApplyShown in figure 13, the external magnetic field H of the said brachium pontis 171 and the physical locations at said brachium pontis 172 places _ApplyMagnetic field intensity and said brachium pontis 173 and the external magnetic field H of the physical locations at said brachium pontis 174 places _ApplyMagnetic field intensity different; The external magnetic field H of the said brachium pontis 175 and the physical locations at said brachium pontis 176 places _ApplyMagnetic field intensity and said brachium pontis 177 and the external magnetic field H of the physical locations at said brachium pontis 178 places _ApplyMagnetic field intensity different.The both sides of each brachium pontis of the said bridge 17 of enjoying a double blessing all are provided with the said permanent magnet 14 of pair of angled.Two input ends of the said bridge 17 of enjoying a double blessing for example are respectively IN5 and IN6, for example said input end IN6 ground connection.Four output terminals of the said bridge 17 of enjoying a double blessing for example are respectively OUT4, OUT5, OUT6 and OUT7.Between said input end IN5 and said input end IN6, apply steady voltage V _BiasThe variation size of the resistance value R8 of the resistance value R7 of said brachium pontis 171 or said brachium pontis 172 varies in size with the variation of the resistance value R10 of the resistance value R9 of said brachium pontis 173 or said brachium pontis 174; The variation size of the resistance value R12 of the resistance value R11 of said brachium pontis 175 or said brachium pontis 176 varies in size with the variation of the resistance value R14 of the resistance value R13 of said brachium pontis 177 or said brachium pontis 178, and said output terminal OUT4, said output terminal OUT5, said output terminal OUT6 and said output terminal OUT7 will distinguish output voltage V 4, V5, V6 and V7.The said bridge 17 output two-way voltage signal V that enjoy a double blessing _OUT4=(V5-V4) and V _OUT5=(V7-V6).

In the actual fabrication of magnetic resistance sensor, said half-bridge 15, said full-bridge 16 or the said bridge 17 of enjoying a double blessing can adopt the disposable preparation of identical technology to accomplish on same substrate, are commonly referred to the one chip magnetic resistance sensor; Also can on same substrate, adopt identical prepared to go out a plurality of said MTJ elements 11; Then with the 11 cutting back encapsulation separately of an a plurality of said MTJ element; And through lead-in wire a said MTJ element 11 is electrically connected and is connected into a plurality of said MTJ element groups 13, again should a plurality of said MTJ element groups 13 being electrically connected is connected into said half-bridge 15, said full-bridge 16 or the said bridge 17 of enjoying a double blessing.The magnetic resistance sensor of the magnetic resistance sensor of one chip encapsulation or the encapsulation of multicore sheet; (Application Specific Integrated Circuit is ASIC) or on the packaging pin of lead frame can be connected to special IC through its external pad.

Shown in figure 15, the magneto-resistor gear sensor 18 that present embodiment provides comprises the soft magnetic bodies 184 and the shell 185 of magnetic sensing chip 181, permanent magnet 182, control circuit 183, spill.Said magnetic sensing chip 181, said permanent magnet 182, said control circuit 183 and said soft magnetic bodies 184 are integrated in the said shell 185.Said magnetic sensing chip 181 comprises at least one electric bridge; This electric bridge is said half-bridge 15, said full-bridge 16 or the said bridge 17 of enjoying a double blessing; Each brachium pontis of said half-bridge 15, said full-bridge 16 or the said bridge 17 of enjoying a double blessing comprises at least one said MTJ element group 13, and a said MTJ element group 13 comprises an a plurality of said MTJ element 11 of series connection and/or parallel connection.Said magnetic sensing chip 181 is electrically connected with said control circuit 183.Said soft magnetic bodies 184 is arranged between said magnetic sensing chip 181 and the said permanent magnet 182, and the opening of said soft magnetic bodies 184 is towards said magnetic sensing chip 181.In the present embodiment, said magnetic sensing chip 181 comprises for example said bridge 17 of enjoying a double blessing, and each brachium pontis of the said bridge 17 of enjoying a double blessing comprises for example said MTJ element group 13.Said permanent magnet 182 is used to produce external magnetic field H _ApplyAnd the gear of being processed by ferromagnetic material is magnetized.Said soft magnetic bodies 184 is used to make the external magnetic field H of said permanent magnet 182 generations _ApplyComponent along said sensitive direction 1171 reduces, thereby guarantees that the said MTJ element 11 in the said magnetic sensing chip 181 is operated in its linear work district.In when, between gear and the said magnetic sensing chip 181 relative motion taking place when, the external magnetic field H at place, said magnetic sensing chip 181 positions _ApplyMagnetic field intensity will change.Said magnetic sensing chip 181 is used to respond to the external magnetic field H of its position _ApplyMagnetic field intensity variation and to said control circuit 183 output voltage signals.Said control circuit 183 is used for the voltage signal of said magnetic sensing chip 181 outputs is handled and changed.In the present embodiment, said control circuit 183 can convert the sine-shaped voltage signal of said magnetic sensing chip 181 outputs into the voltage signal of square waveform.

In the present embodiment, for example said magneto-resistor gear sensor 18 transfixions, gear movement, shown in figure 15.When diverse location point A, B, C, D and E on the gear passed through said magneto-resistor gear sensor successively, the for example sine-shaped voltage signal of said magneto-resistor gear sensor 18 outputs was shown in figure 16.Can confirm the particular location of a tooth to be detected of gear according to the corresponding relation of the for example sinusoidal waveform of the voltage signal of said magneto-resistor gear sensor 18 outputs and location point.When the gear hypodontia, the sine-shaped voltage signal of said magneto-resistor gear sensor 18 outputs and the voltage signal of square waveform are shown in figure 17.Can confirm whether hypodontia of gear according to the for example sinusoidal waveform of the voltage signal of said magneto-resistor gear sensor 18 outputs or square waveform.If the gear hypodontia can be confirmed the particular location of hypodontia according to the corresponding relation of the for example sinusoidal waveform of the voltage signal of said magneto-resistor gear sensor 18 outputs or square waveform and location point.Because the said magnetic sensing chip 181 of the said magneto-resistor gear sensor 18 that present embodiment provides adopts the said bridge 17 of enjoying a double blessing, therefore said magneto-resistor gear sensor 18 can be exported two-way voltage signal V _OUT4And V _OUT5, shown in figure 18, according to this two-way voltage signal V _OUT4And V _OUT5Phase differential can confirm the direction of motion of gear.When using said magneto-resistor gear sensor 18, the external magnetic field H that said permanent magnet 182 produces is removed in the position at said magnetic sensing chip 181 places _ApplyOutside disturbing magnetic field can be regarded as common mode magnetic field.Because said magnetic sensing chip 181 adopts the said bridge 17 of enjoying a double blessing, and the bridge of enjoying a double blessing has the ability of very strong inhibition common mode magnetic interference, and therefore said magneto-resistor gear sensor 18 is not easy to receive and removes the external magnetic field H that said permanent magnet 182 produces _ApplyOutside the interference of disturbing magnetic field.

Embodiment 2:

The structural representation of the 2nd MTJ element 21 that Fig. 2 provides for present embodiment.Said the 2nd MTJ element 21 is a multi-layer film structure; As shown in Figure 2, it comprises insulation course 212, bottom electrode layer 213, pinning layer 214, nailed layer 215, tunnel barrier layer 216, magnetic free layer 217, biasing layer 218 and the top electrode layer 219 that is deposited on successively on the substrate 211.Said nailed layer 215 is a ferromagnetic layer with said magnetic free layer 217.The material of said nailed layer 215 and said magnetic free layer 217 comprises Fe, Co, Ni, FeCo, FeNi, FeCo or FeCoNi.Said nailed layer 215 also can be the composite bed that ferromagnetic layer, Ru layer and ferromagnetic layer form, for example the composite bed of FeCo layer, Ru layer and the formation of FeCo layer.Said pinning layer 214 is an inverse ferric magnetosphere, and its material comprises PtMn, IrMn or FeMn.Exchange-coupling interaction between said pinning layer 214 and the said nailed layer 215 makes the magnetic moment direction 2151 of said nailed layer 215 be pinned at a direction, and outside magnetic field H _ApplyEffect said magnetic moment direction 2151 down remains unchanged.Said tunnel barrier layer 216 comprises MgO or Al ₂O ₃The magnetic moment direction 2171 of said magnetic free layer 217 can be with external magnetic field H _ApplyChange and change.Outside magnetic field H _ApplyEffect under, the magnetic moment direction 2171 of said magnetic free layer 217 can be from progressively changing into the magnetic moment direction 2151 antiparallel directions with said nailed layer 215 with the magnetic moment direction 2151 parallel directions of said nailed layer 215, and vice versa.Said biasing layer 218 is inverse ferric magnetosphere or magnetic layer.Exchange-coupling interaction between said biasing layer 218 and the said magnetic free layer 217 makes said biasing layer 218 the bias magnetic field H perpendicular to the sensitive direction of said the 2nd MTJ element 21 to be provided for said magnetic free layer 217 _CrossThrough changing said bias magnetic field H _CrossCan adjust the saturation field of said the 2nd MTJ element 21, and then adjust the sensitivity of said the 2nd MTJ element 21.When said biasing layer 218 was inverse ferric magnetosphere, the obstruct temperature of said biasing layer 218 (Blocking Temperature) will be lower than the obstruct temperature of said pinning layer 214.Between said magnetic free layer 217 and said biasing layer 218, also can deposit one deck separation layer, be used to weaken the said bias magnetic field H that said biasing layer 218 provides _CrossThickness through changing separation layer can be adjusted said bias magnetic field H _CrossSize.Said separation layer adopts nonmagnetic substance for example Ta, Ru or Cu usually.Said top electrode layer 219 adopts non-magnetic conductive material usually with said bottom electrode layer 213.The material of said substrate 211 adopts silicon, quartz, pyroceram, GaAs or AlTiC usually.The area of said insulation course 212 is greater than the area of said bottom electrode layer 213.Said top electrode layer 219 is used for being electrically connected with other element with said bottom electrode layer 213.

In the application, can and/or and be unified into one the 2nd MTJ element group 23 with a plurality of said the 2nd MTJ elements 21 series connection.In the present embodiment, said the 2nd MTJ element group 23 is formed in parallel by for example four said the 2nd MTJ elements 21, and the sensitive direction of four said the 2nd MTJ elements 21 of said the 2nd MTJ element group 23 is identical.Said the 2nd MTJ element group 23 is electrically connected with the for example said ohmmeter 12 of other element.Can the brachium pontis of said the 2nd a MTJ element group 23 as electric bridge also can be used as a plurality of said the 2nd MTJ element group 23 of series connection and/or parallel connection a brachium pontis of electric bridge.Need to prove, when adopting said the 2nd MTJ element group 23 in the electric bridge, the said permanent magnet 14 of inclination need be set in the both sides of said the 2nd MTJ element group 23.In the present embodiment, each brachium pontis of said half-bridge 15, said full-bridge 16 and the said bridge 17 of enjoying a double blessing adopts for example said the 2nd MTJ element group 23.

Adopt the situation of said the 2nd MTJ element group 23 identical in the magneto-resistor gear sensor 18 with embodiment 1.

Said sensor is a sensitive element with the MTJ element; Compare with the sensor that with Hall element, AMR element or GMR element is sensitive element, the temperature stability of said sensor is better, sensitivity is higher, power consumption is lower, the linearity is better, the linear work district is wideer, structure is simpler.Said sensor is provided with the soft magnetic bodies of spill, external magnetic field that permanent magnet produces is reduced along the component of MTJ element sensitive direction, thereby guarantee that the MTJ element in the magnetic sensing chip is operated in its linear work district, make said sensor performance be improved significantly.The magnetic sensing chip of said sensor adopts full-bridge, makes said sensor be not easy to receive the interference of the disturbing magnetic field the external magnetic field that produces except that said permanent magnet.In a kind of preferred embodiment; The both sides of MTJ element are provided with the permanent magnet of pair of angled; The magnetic field that the permanent magnet of this inclination produces provides bias magnetic field perpendicular to the component of MTJ element sensitive direction for the MTJ element; Can adjust the saturation field of MTJ element through changing this bias magnetic field, thereby obtain to have highly sensitive sensor, or can realize the sensor of different sensitivity as required.In a kind of preferred embodiment; The both sides of MTJ element are provided with the permanent magnet of pair of angled; The nile coupled field of MTJ element can be eliminated in the magnetic field that the permanent magnet of this inclination produces along the component of MTJ element sensitive direction; Thereby the working point that guarantees the MTJ element is in its linear work district, has improved the linearity of said sensor.In another kind of preferred embodiment; The magnetic free layer of MTJ element is provided with the biasing layer; This biasing layer can provide the bias magnetic field perpendicular to MTJ element sensitive direction for the magnetic free layer; Can adjust the saturation field of MTJ element through changing this bias magnetic field, thereby obtain to have highly sensitive sensor, or can realize the sensor of different sensitivity as required.Said sensor can be confirmed the position of certain tooth in the gear, when the gear hypodontia, can also confirm the position of hypodontia.Said sensor not only can be confirmed the movement velocity of gear, and can confirm the direction of motion of gear.Said sensor both had been applicable to the linear gear, also was applicable to circular gear.Said sensor helps realizing large-scale production cheaply.

Should be appreciated that the above detailed description of the technical scheme of the utility model being carried out by preferred embodiment is schematic and nonrestrictive.Those of ordinary skill in the art can make amendment to the technical scheme that each embodiment put down in writing on the basis of reading the utility model instructions, perhaps part technical characterictic wherein is equal to replacement; And these are revised or replacement, do not make the spirit and the scope of each embodiment technical scheme of essence disengaging the utility model of relevant art scheme.

Claims (18)

1. the magneto-resistor gear sensor is characterized in that, this sensor comprises magnetic sensing chip (181) and first permanent magnet (182), and said magnetic sensing chip (181) comprises at least one electric bridge, and each brachium pontis of this electric bridge comprises at least one MTJ element group (13,23).

2. magneto-resistor gear sensor according to claim 1; It is characterized in that; Said sensor further comprises the soft magnetic bodies (184) that is arranged at the spill between said magnetic sensing chip (181) and said first permanent magnet (182), and the opening of said soft magnetic bodies (184) is towards said magnetic sensing chip (181).

3. magneto-resistor gear sensor according to claim 1 is characterized in that, said at least one MTJ element group is a plurality of MTJ element groups, and these a plurality of MTJ element groups are connected and/or are connected in parallel.

4. magneto-resistor gear sensor according to claim 3 is characterized in that, these a plurality of MTJ element groups are connected and/or are connected in parallel with same sensitive direction.

5. magneto-resistor gear sensor according to claim 1 is characterized in that, each comprises that the brachium pontis of MTJ element group has identical sensitive direction.

6. magneto-resistor gear sensor according to claim 1 is characterized in that, said electric bridge is half-bridge (15), full-bridge (16) or the bridge of enjoying a double blessing (17).

7. magneto-resistor gear sensor according to claim 1 is characterized in that, each MTJ element group (13,23) comprises series connection and/or a plurality of MTJ elements (11,21) that are connected in parallel.

8. magneto-resistor gear sensor according to claim 1 is characterized in that, each MTJ element group (13,23) comprises a plurality of MTJ elements (11,21) of connecting and/or being connected in parallel with same sensitive direction.

9. according to claim 7 or 8 described magneto-resistor gear sensors, it is characterized in that each MTJ element (11) is a multi-layer film structure, comprise pinning layer (114), nailed layer (115), tunnel barrier layer (116) and the magnetic free layer (117) of deposition successively.

10. magneto-resistor gear sensor according to claim 9; It is characterized in that; The both sides of said each MTJ element group (13) are provided with a pair of second permanent magnet (14), and this is obliquely installed with respect to the sensitive direction of this MTJ element group (13) second permanent magnet (14) and is used for bias magnetic field to said MTJ element group (13) being provided.

11. magneto-resistor gear sensor according to claim 9; It is characterized in that; The both sides of said each MTJ element group (13) are provided with a pair of second permanent magnet (14), and this is obliquely installed the nile coupled field that is used to eliminate said MTJ element group (13) to second permanent magnet (14) with respect to the sensitive direction of this MTJ element group (13).

12. magneto-resistor gear sensor according to claim 10 is characterized in that, this is obliquely installed the nile coupled field that is further used for eliminating said MTJ element group (13) to second permanent magnet (14) with respect to the sensitive direction of this MTJ element group (13).

13. according to claim 7 or 8 described magneto-resistor gear sensors; It is characterized in that; Each MTJ element (21) is a multi-layer film structure, comprises pinning layer (214), nailed layer (215), tunnel barrier layer (216), magnetic free layer (217) and the biasing layer (218) of deposition successively.

14. magneto-resistor gear sensor according to claim 13 is characterized in that, each MTJ element (21) further comprises the separation layer of being located between said magnetic free layer (217) and the said biasing layer (218).

15. magneto-resistor gear sensor according to claim 1 is characterized in that, said sensor further comprises the control circuit (183) that is electrically connected with said magnetic sensing chip (181).

16. magneto-resistor gear sensor according to claim 15 is characterized in that, said control circuit is confirmed the position of the gear teeth according to the corresponding relation of the voltage signal of said magnetic sensing chip output and gear tooth location point.

17. magneto-resistor gear sensor according to claim 1; It is characterized in that; Said magnetic sensing chip comprises the bridge of enjoying a double blessing, and each brachium pontis of the said bridge of enjoying a double blessing comprises MTJ element group, and said control circuit is confirmed the direction of motion of gear according to the voltage signal of said magnetic sensing chip output.

18. magneto-resistor gear sensor according to claim 1 is characterized in that, said sensor further comprises shell (185).

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