Integrated magnetic field sensor

A magnetic field sensor, such as a magnetoresistor, includes a strip of a layer of a high electron mobility semiconductor whose electrical characteristics vary when a magnetic field is applied thereto on the surface of a body (substrate) of an insulating layer. Conductive contacts are on the strip at the ends thereof and conductive shorting bars are on and spaced along the strip to divide the strip into active regions. The body is mounted on a permanent magnet assembly which includes a magnet and a layer of a ferromagnetic material with the ferromagnetic material extending over the strip. The ferromagnetic layer is in close proximity to only the strip and, more preferably, to only the active regions of the strip so as to confine the magnetic field to the strip.

FIELD OF THE INVENTION 
The present invention relates to an integrated magnetic field sensor, such 
as a magnetoresistor combined with a magnet, and, more particularly, to an 
integrated magnetic field sensor in which the magnetic field is more 
concentrated in the active region of the sensor. 
BACKGROUND OF THE INVENTION 
Magnetic field sensors, such as magnetoresistors, are useful for a variety 
of applications, such as position sensors when used with a magnet. These 
magnetic field sensors are typically made with active elements composed of 
a semiconductor material or semimetal, such as InSb, InAs, In.sub.1-x 
Ga.sub.x As, GaAs, Si or Bi.sub.1-x Sb.sub.x, along with associated metal 
contacts, insulating passivation, etc. These devices are designed to give 
optimum sensitivity, when a magnetic field is applied thereto, to changes 
in impedance, thermal stability, etc. One form of a magnetoresistor, as 
shown in U.S. Pat. No. 4,926,154 (J. P. Heremans et al.), issued May 15, 
1990, and entitled "Indium Arsenide Magnetoresistor," comprises a layer of 
a high mobility semiconductor material on an insulating substrate. Metal 
contacts are on the layer at the ends thereof and conductive shorting bars 
are on the layer and spaced therealong between the contacts. The shorting 
bars divide the semiconductor layer into a plurality of small active 
regions having a relatively small length-to-width ratio and which are all 
connected in series. The semiconductor layer may extend along a meandering 
path to increase device resistance. 
To use such a magnetoresistor as a position measuring system, it is mounted 
on a magnet and used along with a ferromagnetic part, such as a movable 
gear tooth. The movement of the gear tooth across the magnetoresistor 
changes the magnetic field strength through the magnetoresistor and 
thereby changes its resistance. One such system is shown in U.S. Pat. No. 
4,939,456 (D. T. Morelli et al.), issued Jul. 3, 1990 and entitled 
"Position Sensor Including a Thin Film lndium Arsenide Magnetoresistor on 
a Permanent Magnet." When the magnetoresistor is mounted on a magnet made 
of a conductive material, a dielectric insulating layer is provided 
between the magnet and the magnetoresistor to insulate one from the other. 
Also, it has been found desirable to coat the magnet with a high 
permeability ferromagnetic layer to increase the sensitivity of the 
device, such as disclosed in U.S. Pat. No. 4,926,122 to T. Schroeder et 
al., issued May 15, 1990. However, it would be desirable to further 
increase the sensitivity of the device by concentrating the magnetic field 
primarily to the active areas of the sensor. 
SUMMARY OF THE INVENTION 
The present invention is directed to a magnetic field sensor of the type 
having a strip of a material whose characteristics vary when the strip is 
subjected to a magnetic field and which is divided into active regions. 
The strip is mounted on a magnet with a layer of a ferromagnetic material 
being across the strip. The ferromagnetic layer is in close proximity only 
to the strip and, more particularly, to only the active regions of the 
strip. 
More particularly, the magnetic field sensor of the present invention 
comprises a body having on a surface thereof a strip of a layer of a 
material whose characteristics vary when a magnetic field is applied 
thereto. Conductive regions are on the strip and form active regions of 
the strip therebetween. The body is mounted on a magnet assembly. A layer 
of a ferromagnetic material is across the strip with the ferromagnetic 
material extending in close proximity to only the strip. 
The invention will be better understood from the following more detailed 
description taken with the accompanying drawings.

DETAILED DESCRIPTION 
Referring now to FIG. 1, there is shown a perspective view of a 
magnetoresistor 10 in accordance with the present invention. The 
magnetoresistor 10 comprises a body (substrate) 12 of an insulating 
material, such as semi-insulating GaAs, InP, Si or Si coated with a thin 
film of an insulating InP, GaAs or Al.sub.1-x Ga.sub.x As, having on a 
surface 14 thereof a strip 16 of a layer of a material whose 
characteristics, such as resistance, vary when a magnetic field is applied 
thereto. Preferably, the strip 16 is of a high electron mobility 
semiconductor material, such as InSb or InAs, which is doped to n-type 
conductivity to increase the stability of carrier density with temperature 
fluctuations. Also, it is preferable that the layer forming the strip 16 
be relatively thin, typically of a thickness of no greater than about 5 
microns. A pair of conductive contacts 18 and 20, typically of a metal, 
are on the semiconductor strip 16 at opposite ends of the strip 16 so as 
to be spaced apart. On the surface of the semiconductor strip 16 between 
the contacts 18 and 20 are usually shorting bars 22 of a conductive 
material, such as a metal. Two such shorting bars 22 are shown. The 
shorting bars 22 are uniformly spaced apart along the semiconductor strip 
16 between the contacts 18 and 20. This divides the semiconductor strip 16 
into a plurality of active regions 16a which are electrically connected in 
series. The spacing between the shorting bars 22 is such that the active 
regions 16a preferably have a relatively small length (distance along 
semiconductor layer between shorting bars) to width (width of 
semiconductor layer) ratio. 
On the surface of each of the active regions 16a of the semiconductor strip 
16 are a plurality of separated layers 24 of a ferromagnetic material. The 
ferromagnetic material is preferably magnetically "soft" in that it has 
low coercivity, high magnetic permeability and high saturation flux 
density. Such materials include iron, nickel, cobalt and various alloys 
thereof. The width of the ferromagnetic layers 24 corresponds to the 
smallest lateral dimension of the active regions 16a of the strip 16. 
Since these ferromagnetic materials are usually conductive, a layer 26 of 
a dielectric insulator is provided between each of the ferromagnetic 
layers 24 and the surface of its respective active region 16a. The body 12 
is mounted on a permanent magnet assembly 27. The permanent magnet 
assembly 27 comprises a permanent magnet 28, preferably having thereon a 
soft ferromagnetic layer 29 which covers essentially the entire surface of 
the permanent magnet 28, as disclosed in U.S. Pat. No. 4,926,122. The 
permanent magnet assembly 27 is typically much larger than the 
magnetoresistor assembly 10. If the magnet 28 is of a conductive material, 
a layer 30 of a dielectric insulating material may be provided between the 
magnet 28 and the body 12. The dielectric insulating layer 30 is not 
needed if the body 12 is sufficiently insulating. Terminal wires 32 and 33 
are secured to the contacts 18 and 20, respectively. 
In the magnetoresistor 10, the ferromagnetic layers 24 are in close 
proximity to only the active regions 16a of the semiconductor layer 16. 
This causes the magnetic field to be concentrated in the active regions 
16a and not in the inactive regions under the contacts 18 and 20 and the 
shorting bars 22. This, in turn, improves the sensitivity of the 
magnetoresistor 10. 
The aspect ratio of the ferromagnetic layers 24 is defined as their height, 
or thickness, divided by their width (their smallest lateral dimension). 
Ferromagnetic layers with an aspect ratio of at least in the order of 1 
(e.g., between 0.5 and 2) are preferable. This aspect ratio has a greater 
effect in concentrating the magnetic flux than smaller aspect ratios 
(e.g., 0.1). However, very large aspect ratios would be undesirable if the 
magnetic flux in the ferromagnetic layers 24 exceeds the saturation 
magnetization of the ferromagnetic material. A problem with small aspect 
ratios in nominally isotropic ferromagnetic materials is that there is a 
geometric anisotropic which tends to make the ferromagnetic layers 
magnetize laterally rather than vertically. This geometric anisotropic can 
be overcome by the use of single crystalline or partially oriented 
polycrystalline ferromagnetic materials in which the easy magnetization 
axis is perpendicular to the plane of the film. 
Referring now to FIG. 2, there is shown a cross-sectional view of another 
magnetoresistor 34 in accordance with the present invention. The 
magnetoresistor 34 comprises a body (substrate) 36 of an insulating 
material, such as semi-insulating GaAs, InP, Si or Si coated with a thin 
film of insulating InP, GaAs or Al.sub.1-x Ga.sub.x As, having a surface 
38. On the surface 38 is a strip 40 of a layer of a high electron mobility 
semiconductor material whose characteristics, such as resistance, vary 
when a magnetic field is applied thereto. On the semiconductor strip 40 
are conductive contacts 42 and 44 which are at the ends of the 
semiconductor strip 40. Conductive shorting bars 46 are on the 
semiconductor layer 40 between the contacts 42 and 44. The shorting bars 
46 are spaced apart along the semiconductor strip 40 to divide it into 
active regions 40a preferably having a low length-to-width ratio. 
The body 36 is mounted on a permanent magnet 48 with the semiconductor 
strip 40, contacts 42 and 44 and the shorting bars 46 facing a surface 50 
of the magnet 48. On the surface 50 of the magnet 48 is a layer 52 of a 
ferromagnetic material. The ferromagnetic layer 52 has spaced recesses 54 
therein which are aligned with the contacts 42 and 44 and the shorting 
bars 46. Thus, the ferromagnetic layer 52 is in close proximity to only 
the active regions 40a of the semiconductor layer 40. The recesses 54 may, 
as shown, extend only part way through the thickness of the ferromagnetic 
layer 52 or they may extend completely through the ferromagnetic layer 52. 
The recesses 54 may be formed by a stamping process or by using 
photolithography and a chemical etching process. Although the recesses 54 
are shown to be rectangular, they may have other shapes, such as 
triangular or cylindrical. These other shapes may be easier to manufacture 
and may be more effective in concentrating the magnetic flux into the 
desired regions of the sensor. 
In the magnetoresistor 34, the ferromagnetic layer 52 serves a dual role. 
By extending the ferromagnetic layer 52 over essentially the entire 
surface 50 of the magnet 48, it is part of the permanent magnet assembly. 
With recesses 54, it also concentrates the flux toward the active areas 
40a of the semiconductor strips 40. The recesses 54 may extend over the 
entire surface of the magnetic assembly if desired. Other recess areas may 
be added, if desired, to aid in the optical alignment of the sensor chip 
36 with the recesses 54. 
The body 36 is secured to the magnet 48 by a layer 56 of an insulating 
adhesive material which is between the ferromagnetic layer 52 and the 
semiconductor strip 40, contacts 42 and 44 and the shorting bars 46. 
Conductive contacts 58 and 60 are on the ferromagnetic layer 52 and are 
insulated from the ferromagnetic layer 52 by a layer 61 of a dielectric 
insulating material. The contacts 58 and 60 are engaged by the contacts 42 
and 44, respectively, so as to be electrically connected thereto. Terminal 
wires 62 are connected to the contacts 58 and 60 so as to be electrically 
connected to the semiconductor strip 40. 
Referring now to FIG. 3, there is shown a top plan view of still another 
magnetoresistor 66 in accordance with the present invention. The 
magnetoresistor 66 comprises a body (substrate) 68 of an insulating 
material, such as semi-insulating GaAs or InP. On a surface 70 of the body 
68 is a strip 72 of a high mobility semiconductor material which extends 
in a meandering path (shown as two connected U's or an "S"). Conductive 
contacts 74 and 76 are on the semiconductor strip 72 at the ends thereof. 
Conductive shorting bars 78 are on the semiconductor strip 72 spaced along 
the strip between the contacts 74 and 76 to divide the strip 72 into 
active regions 72a. 
The body 68 is mounted on a surface 80 of a permanent magnet assembly 82. 
On the magnet assembly surface 80 between the magnet assembly 82 and the 
body 68 is a layer 84 of a ferromagnetic material. Regions 86 of the 
ferromagnetic layer 84 which are along the sides of the strip 72 and do 
not extend over the active regions 72a of the strip 72 are either removed 
or have recesses therein. Thus, the ferromagnetic layer 84 is in close 
proximity to only the strip 70. Conductive leads 88 and 89 are connected 
to the contacts 74 and 76, respectively. Although the ferromagnetic layer 
84 is shown as being on the surface 88 of the permanent magnet 82, the 
ferromagnetic layer 84 can be coated directly on semiconductor strip 72. 
In a prepared embodiment of the invention, in the magnetoresistor 66, the 
ferromagnetic layer 84 is in close proximity to only the semiconductor 
strip 72 so as to concentrate the magnetic field to the strip 72 and away 
from any inactive portion of the device. This improves the sensitivity of 
the magnetoresistor 66. To further improve the sensitivity of the 
magnetoresistor 66, the ferromagnetic layer 84 may be defined to be in 
close proximity to only the active regions 72a of the semiconductor strip 
72. 
Referring now to FIG. 4, there is shown a top plan view of a dual 
magnetoresistor 90 in accordance with the present invention. The 
magnetoresistor 90 comprises a body 92 (substrate) of an insulating 
material, such as semi-insulating GaAs or InP. On a surface 94 of the body 
92 are two strips 96 and 98 of a high mobility semiconductor material. The 
strips 96 and 98 are each in the form of a U and are arranged in parallel 
positions. A conductive connecting contact 100 is on the body surface 94 
and contacts one end of each of the strips 96 and 98. Separate conductive 
contacts 102 and 104 are on the other ends of each of the strips 96 and 
98, respectively. Conductive shorting bars 106 are on the strip 96 and are 
spaced therealong between the contacts 100 and 102 to divide the strip 96 
into a plurality of active regions 96a. Conductive shorting bars 108 are 
on the strip 98 and are spaced therealong between the contacts 100 and 104 
to divide the strip 98 into a plurality of active regions 98a. 
A separate layer 110 of a ferromagnetic material is over each of the strips 
96 and 98. Each ferromagnetic layer 110 is defined so that it is in close 
proximity to only its respective strip 96 and 98. This can be achieved by 
either completely removing or providing recesses in the portions of the 
ferromagnetic layers 110 not over the strips 96 and 98. The body 92 is 
mounted on a permanent magnet assembly (not shown). The magnet assembly 
may be on the same side or the opposite side of the body 92 as the strips 
96 and 98. The ferromagnetic layers 110 may be coated on the magnet or on 
the body 92. Separate terminals (wires), not shown, are connected to the 
contacts 100, 102 and 104. 
In the dual magnetoresistor 90, the ferromagnetic layers 110 are in close 
proximity to only the semiconductor strips 96 and 98 so as to concentrate 
the magnetic fields to the semiconductor strips 96 and 98 and thereby 
improve the sensitivity of the magnetoresistor 90. The sensitivity of the 
magnetoresistor 90 can be further improved by defining the ferromagnetic 
layers 110 so that they are in close proximity to only the active regions 
96a and 98a of the strips 96 and 98. 
Referring now to FIG. 5, there is shown a cross-sectional view of a portion 
of another magnetoresistor 112 in accordance with the present invention. 
The magnetoresistor 112 comprises a body (substrate) 114 of an insulating 
material, such as semi-insulating GaAs or InP. On a surface 116 of the 
body 114 are a plurality of spaced layers 118 of a ferromagnetic material. 
A layer 120 of an insulating material is on the body surface 116 and over 
the ferromagnetic layers 118. A strip 122 of a layer of a high mobility 
semiconductor material is on the insulating layer 120. Conductive shorting 
bars 124 are on the semiconductor strip 122 and are spaced therealong to 
divide the semiconductor strip 122 into a plurality of active regions 
122a. The shorting bars 124 are positioned over the spaces between the 
ferromagnetic layers 118 so that each of the active regions 122a is 
directly over a separate ferromagnetic layer 118. Thus, the ferromagnetic 
layers 118 are in close proximity to the active regions 122a. A permanent 
magnet assembly (not shown) is mounted on the magnetoresistor 112 at 
either side of the body 114. 
The magnetoresistor 112 can be made by coating a layer of a ferromagnetic 
material, such as iron or iron oxide, on the surface 116 of the body 114. 
The layer is defined, using photolithography and etching, to form the 
spaced layers 118. The insulating layer 120, such as of silicon dioxide, 
silicon nitride, aluminum nitride, gallium nitride or aluminum oxide, is 
deposited on the body surface 116 and over the ferromagnetic layers 118. 
Openings are formed in the insulating layer 120 to expose the body 114 in 
certain regions. Selective growth of gallium arsenide is then carried out 
in the exposed regions of the body 114 using the technique described in 
the article entitled, "Anisotropic Lateral Growth in GaAs MOCVD Layers on 
(001) Substrates," by H. Asai, published in Journal of Crystal Growth, 
Vol. 80, 1987, pgs. 425-433. This is followed by changing the gallium 
arsenide growth conditions to obtain lateral epitaxial growth as described 
in the article entitled, "Lateral Epitaxial Overgrowth of GaAs by 
Organometallic Chemical Vapor Deposition," by R. P. Gale et al., published 
in Applied Physics Letters, Vol. 41(6), Sep. 15, 1982, pgs. 545-547. A 
thin layer of the high mobility semiconductor material, such as InSb or 
InAs, is then deposited on the gallium arsenide layer and defined to form 
the strip 122. A metal layer is then deposited over the semiconductor 
strip 122 and defined, using photolithographic techniques and etching, to 
form the shorting bars 124. 
Referring now to FIG. 6, there is shown a cross-sectional view of a 
magnetoresistor 100, which is similar to the magnetoresistor 10 shown in 
FIG. 1. Therefore, the parts of the magnetoresistor 100 which are the same 
as those of the magnetoresistor 10 will be indicated by the same reference 
number with the prefix "1". The magnetoresistor 100 comprises a body 112 
of an insulating material having on a surface 114 thereof a strip 116 of a 
semiconductor material, such as described for the semiconductor strip 16 
of the magnetoresistor 10. Conductive contacts 118 and 120 are on the 
semiconductor strip 116 at opposite ends of the strip 116 and shorting 
bars 122 are uniformly spaced apart along the semiconductor strip 116 
between the contacts 118 and 120. This divides the strip 116 into a 
plurality of active regions 116a. 
On the surface of each of the active regions 116a is a separate layer 124 
of a soft ferromagnetic material. A layer 126 of a dielectric insulator is 
between each of the ferromagnetic layers 124 and the surface of its 
respective active region 116a. The magnetoresistor 100 differs from the 
magnetoresistor 10 in that it includes a layer 125 of a soft ferromagnetic 
material which connects the individual ferromagnetic layers 124 and 
extends over the shorting bars 122. This additional ferromagnetic layer 
125 reduces the flux through the shorting bars 122 and further 
concentrates the flux through the ferromagnetic layers 124 and the active 
regions 116a under them. The body 112 is mounted on a magnet assembly 127 
similar to the magnet assembly 27 shown in FIG. 1. 
Thus, there is provided by the present invention a magnetoresistor 
integrated with a magnet assembly and having a ferromagnetic material 
thereon. The ferromagnetic material is in close proximity to only the 
semiconductor strip of the magnetoresistor so as to confine the magnetic 
field to the semiconductor strip. This provides a more sensitive 
magnetoresistor. The sensitivity is further improved by having the 
ferromagnetic material in close proximity to only the active regions of 
the semiconductor. The ferromagnetic material may be coated on a surface 
of the magnet assembly or directly on the body of the magnetoresistor. 
Also, the ferromagnetic material may be provided only over the 
semiconductor strip(s) or the active regions of the semiconductor strip(s) 
or may be over the entire device and provided with recesses which space 
the ferromagnetic layer from the nonactive portions of the 
magnetoresistor. 
It is to be appreciated and understood that the specific embodiments of the 
invention are merely illustrative of the general principles of the 
invention. Various modifications may be made consistent with the 
principles set forth. For example, although the invention has been 
described as being used in a magnetoresistor, it may be used in other 
magnetic field sensors, such as Hall effect devices, MAGFET devices (see 
the article of H. P. Baltes and R. S. Popovic, published in the 
Proceedings of IEEE, Vol. 74, 1986, pages 1107-1132) or a superlattice 
structure. In a superlattice structure, an antiferromagnetically ordered 
superlattice of materials, such as Co/Cu or Fe/Cr, orders 
ferromagnetically in an applied magnetic field, thus changing the 
electrical resistance of the superlattice (see the article of S. S. 
Parkin, Z. G. Li and D. J. Smith published in Applied Physics Letters, 
Vol. 58, 1991, pages 2710-2712). For example, in a Hall effect device in 
which the active layer has four arms extending from a common point, the 
ferromagnetic layer would be placed under or over the active layer at the 
junction of the four arms. The ferromagnetic layer would preferably have a 
thickness which is comparable to or larger than its lateral dimensions so 
as to have an aspect ratio of the order of unity or greater. 
Still further, various materials can be used for the active layer of the 
magnetic field sensor. Furthermore, in the dual magnetoresistor 90 
described with regard to FIG. 4, which shows two magnetoresistor elements 
96 and 98, the magnetoresistor 90 may have more than two magnetoresistor 
elements if desired. Also, the additional ferromagnetic layer 125 shown in 
FIG. 6 would also be used in the magnetoresistors 66 and 90 shown in FIGS. 
3 and 4. 
In addition, the magnet assemblies of the sensors shown in FIGS. 1, 3, 4 
and 7 have, in addition to the magnet and the ferromagnetic layer covering 
the magnet, a ferromagnetic object, such as a gear which has a position to 
be sensed, moving near the sensor. However, alternatively, the magnet 
assembly (or just the magnet) can be removed. A moving magnetic part, such 
as a wheel which is magnetized differently in different places along its 
circumference, is then moved or rotated near the sensor. This causes the 
magnetic field through the sensor to change, which then allows the 
movement to be sensed.