EP3317685A1 - Electrical component and method for producing an electrical component of this type - Google Patents

Abstract

The invention relates to an electrical component comprising a first package having a first lead frame and a first die attached to the lead frame, and encapsulation material that encapsulates the die and at least portions of the lead frame. The component is characterised by a second package having a second lead frame and encapsulation material that encapsulates at least portions of the lead frame, wherein the encapsulation material of the first package is permanently connected to the encapsulation material of the second package.

Description

 "Electrical component and manufacturing method for producing such an electrical component"

The invention relates to a semiconductor package having a first package with a first leadframe and a chip and encapsulation material attached to the first leadframe encapsulating the chip and at least portions of the leadframe. Likewise, the invention relates to a manufacturing method for producing such an electrical component and an electrical component having an electrical component.

Semiconductor packages are used in many applications. They have a lead frame and a chip attached to the lead frame. An encapsulation material encapsulates the chip and at least parts of the leadframe, most of the outbound electrical leads, throughout the leadframe of the semiconductor package.

The sheath of a chip (often referred to as "the" in English), including the connection points, such as leads, pins or balls, can be referred to as housing or package For such packages, there have been standardization efforts, for example by the JEDEC (formerly Joint Electron Device Engineering Council, now JEDEC Solid State Technology Association.) Packages are commonly used between THROUGH THROUGH THONG THERMAL THERMAL THERMAL THERMAL THERMAL THERMAL THERMAL AND THERMAL MOUNTED THERMAL MOUNTING (THERMALLY MOUNTED THERMAL THERMAL THERMAL TECHNOLOGY)

CONFIRMED U NGSKOPI E Technology - SMT) types. The packages are typically used to attach the chip to a printed circuit board. For this purpose, the chip is connected to an intermediate material (also referred to here as leadframe or "lead frame") Electrical connections, for example wires, lead from the electrical connections of the chip to electrical connections of the package.

These electrical connections can be leads, pins or balls.

From the prior art generic electrical components are known, dje are executed substantially cuboid and have a lower height than width. Often the width is significantly less than the length and the height is significantly less than the width. In such electrical components, it has proved to be problematic, the electrical components edgewise, so to connect standing on one of the narrow sides with a circuit board. In EP 1 775 767 A2 a method is proposed for this purpose.

Based on this prior art, the present invention seeks to provide an electrical component that can be easily connected to a circuit board. Femer the invention has for its object to propose a manufacturing method with which such a component can be produced particularly easily.

This object is achieved by the electrical component according to claim 1, the manufacturing method according to claim 9 and the electrical component according to claim 11.

Embodiments of the invention are set forth in the subclaims and the following description.

The invention is based on the basic idea of taking two packages and firmly connecting the encapsulation material of the first package with the encapsulation material of the second package. This creates an electrical component formed from at least two packages. It has been found that such an electrical component can be connected to a printed circuit board particularly well. This applies in particular to the preferred embodiment, in which the electrical component is to be connected to a narrow side of the first package with a circuit board.

The electrical component according to the invention has a first package with a first leadframe, a chip attached to the first leadframe, and encapsulation material comprising the chip and at least parts of the leadframe encapsulates. In a preferred embodiment, the package is designed as a Surface Mounted Device (SMD).

In a preferred embodiment, the first package and / or the second package is a DFN (Dual Fiat No-Iead Package), QFN (Quad Fiat No Leads Package),

 VCC (Very Thin Quad Fiat pack), LCC (Leadless Ceramic Chip Carrier), LGA MLPQ (Micro Leadframe Package Quad), MLPM (Micro Leadframe Package Micro), MLPD (Micro Leadframe Package Dual), DRMLF (Dual Row Micro Leadframe Package) , Thin Dual Fiat No-Iead Package (TDFN), Ultrathin Dual Fiat Noll.0 lead package, XDFN (eXtreme thin Dual Fiat No-Iead Package), QFN (Quad Fiat No-Iead Package), QFN-TEP (Quad Fiat No-Iead Package with Top Exposed Ped), TQFN (Thin Quad Fiat No-Iead Package), Very Thin Quad Fiat No Leads Package (VQFN), DHVQFN (Dual in-line compatible thermal-thin quad flat package with no leads (NXP)).

 15

 In a particularly preferred embodiment, the first package and the second package are designed according to the same design. The extent to which the encapsulating material encapsulates the chip and the leadframe results from the aforementioned types of construction. Often the chip and the entire lead frame

2 o except for the terminals encapsulated by the encapsulating material.

In a first variant, the second package is empty, ie has no chip arranged in the package. In such an embodiment variant, the second package is essentially used to stably connect the first package with the chip arranged in the encapsulation material to the printed circuit board, in particular if the package is connected to the printed circuit board perpendicular to the usual type and not lying down shall be. Packages can now be produced on a large industrial scale. The disadvantages of adding a second (empty) package are offset by the advantages of more stably connecting the first package to the PCB. In an alternative, likewise preferred embodiment, the second package has a chip attached to the second leadframe. The encapsulating material of the second package encapsulates the chip and at least portions of the leadframe of the second package. The chip in the second package may be identical or similar to the chip in the first package, ie, for example, have sensors with the same measurement principle. However, embodiments are also conceivable in which the chip in the second package is different from the chip in the first package. As a result, a stably connectable to the circuit board electrical component is created, which can take over a plurality of functions. If the chips are designed as measuring sensors, then an electrical component can be created in this way, which can measure with two different measuring methods. With The chip in the first package can be a first measurement method and the chip in the second package a second measurement method can be realized. Furthermore, in the second package passive supporting components such as support magnets can be installed or active components such as coils that support the measurement principle

The encapsulating material of the first package is fixedly connected to the encapsulating material of the second package. Electrical components of the type according to the invention are often handled by gripping arms with suction pipette or the like. For this it is essential that the electrical component is stable in itself. The tight connection of the encapsulating material of the first package with the

Encapsulation material of the second package can be made non-positively or positively. In a particularly preferred embodiment, the encapsulation material of the first package is therefore connected by means of joining with the encapsulation material of the second package. Particularly preferably, the encapsulating material of the first package is bonded to the encapsulating material of the second package. However, the use of friction welding or ultrasonic welding for joining the encapsulating material is also conceivable.

In principle, it is conceivable that any connection surface of the encapsulating material of the first package with any

Connecting surface of the encapsulating material of the second package is connected by joining. So it is conceivable, for example, that the connection surfaces are profiled, for example, be roughened or provided with sawtooth profiles to support the mating connection. In a particularly preferred embodiment, however, the connection surfaces are planar. Thus, a first planar connection surface is formed on the encapsulating material of the first package, and a second planar connection surface is formed on the encapsulating material of the second package, and the first planar connection surface is joined to the second planar connection surface by joining. As a result, on the one hand the processing cost of the encapsulating material is reduced. Level connection surfaces are already present in the majority of standardized packages and the corresponding production processes for such surfaces have already been implemented. On the other hand can be reduced by the flat running of the connection surface, the height of the electrical component. There is no need to provide additional projections which would increase the overall height of the electrical component.

In a majority of the packages known from the prior art, the leadframe has a flat receiving surface to which the chip is attached. In a preferred embodiment, the chip is on a flat receiving surface of the first lead frame attached to the first lead frame and the first planar connection surface parallel to the receiving surface of the first lead frame executed. Additionally or alternatively, the second leadframe on a flat receiving surface for a chip, wherein the second planar connection surface is parallel to the receiving surface of the second leadframe is executed. Even with the parallel arrangement of the connection surfaces to the receiving surfaces of the lead frame, the height of the electrical component can be reduced.

The majority of known from the prior art, in particular the majority of standardized packages have a substantially cuboid shape. Often, the four side surfaces of the cuboid are smaller than the surface of the top of the cuboid. In a particularly preferred embodiment, to form the electrical component according to the invention, these upper sides of cuboid packages are firmly connected to one another. The tops of the cuboid packages then each form the planar connection surfaces of the respective package.

In a preferred embodiment, the first package has externally accessible electrical connections. Additionally or alternatively, the second package has externally accessible electrical connections. If packages with standardized designs are used for the production of the electrical component according to the invention, the arrangement of the electrical connections of the first package and of the second package results from this standardized design. Particularly preferably, a design of the type DFN or TDFN is used as the first package and as the second package.

In a particularly preferred embodiment, the first package is cuboidal. Additionally or alternatively, the second package may be configured cuboid. In a preferred embodiment, the electrical component itself is cuboidal. This can result from the fact that both the first package and the second package are cuboid, so that after the joining of the two packages, the resulting electrical component is also cuboid. The execution of the first package, or the second package as a cuboid component simplifies both the handling of the packages in producing the electrical component according to the invention. Further, as stated above, the cuboid shape provides good bonding surfaces by which the first package and the second package can be firmly joined together. Running the electrical component in cuboid shape also offers the advantage of good handling and the ability to arrange this electrical component well on a printed circuit board. Cuboid components have twelve edges. They have an upper side and a lower side and four side surfaces arranged at right angles to one another and arranged at right angles to the upper side and the lower side. A side surface has four edges, namely an edge to the bottom, an edge to the top and a first edge to a first further side surface and a second edge to a second, the first oppositely disposed further side surface. In a preferred embodiment, an electrical connection is formed in the region of one of these four edges of a side surface. Most preferably, the port has a mating surface that is partially in the surface of this page. Particularly preferably, the connection forms part of an edge. That is, a part of the edge is formed on the electric terminal. The electrical connection can then have a partial surface which is located in the surface of the page as well as a further partial surface located in the adjacent surface, ie depending on the position of the edge in the surface of the underside, the surface of the upper side or in the surface of a the adjacent other pages is located.

In a preferred embodiment, electrical connections of the first package are in the region of a first edge of this side and in the region of a second edge, wherein the first edge and the second edge are arranged at right angles to each other. In a particularly preferred embodiment, the first package has electrical connections only at these two edges. In a likewise preferred embodiment, the first package has electrical connections in the region of three edges of this side surface, wherein the three edges merge into one another and are arranged at right angles to one another. In a particularly preferred embodiment, the first package has connections only at these three edges.

In a particularly preferred embodiment, the second package has electrical connections which are arranged on the edges of the cuboid forming the second package in the preferred embodiment, comparable to the first package. Particularly preferred is a design in which the electrical component is cuboid-shaped and has on at least one side neither electrical connections of the first package nor electrical connections of the second package. Such a connection-free side of the electrical component is advantageous if the chip has a sensor in the first package, for example a sensor sensitive to magnetic fields. If one side of the electrical component is executed connection-free, then disturbing influences are prevented at least on this side. In a particularly preferred embodiment, the electrical component is designed to be symmetrical, at least with regard to the lead frames and the shape of the encapsulation material. More specifically, a first planar connection surface is formed on the encapsulant of the first package, and a second planar connection surface is formed on the encapsulation material of the second package, the first planar connection surface being joined to the second planar connection surface, the lead frame and the encapsulation material of the first package with respect to the plane parallel to the first connection surface and the second connection surface, located centrally between the first connection surface and the second connection surface, are mirror-symmetrical to the lead frame and the encapsulation material of the second package. The symmetrical forming of the electrical component offers the advantage of being able to handle it well.

In a preferred embodiment, the chip has a magnetic field-sensitive sensor. Particularly preferably, the chip has a magnetoresistive sensor. In particular, the sensor may have the anisotropic magnetoresistive effect (AMR effect) or the gigantic magnetoresistive effect (GMR effect). However, the sensor may also have other effects, such as Giant Magneto Impedance (GMI), Tunnel Magnetoresistance Effect (TMR) or the Hall effect or all sensors whose direction of measurement is in the Z axis.

In a preferred embodiment, the magnetic-field-sensitive sensor contains at least one Wheatstone bridge. This consists in particular of several locally distributed over the chip sensor elements (in particular a plurality of locally distributed over the chip resistors). In a preferred embodiment, these are interconnected in such a way that local field direction or field strength differences between the individual sensor elements which are generated by a transmitter magnet arrangement are used to generate a sensor signal dependent on a transmitter position or a sensor angle relative to the sensor.

In a preferred embodiment, the electrical component has a plurality of magnetic field-sensitive sensors. There are conceivable designs in which a plurality of magnetic field-sensitive sensors are provided in one of the packages. However, particularly preferred are designs in which at least one magnetic field-sensitive sensor is provided in each package. In this case, in a first embodiment, the magnetic field-sensitive sensor may be similar sensor chips, in particular preferably have an identical structure. As a result, for example, redundant measurements can be performed and thus the precision of the generated signal can be increased. In a second embodiment, at least two different magnetic field-sensitive sensors are provided. These can be designed for the detection of the fields of different encoders or locally different encoder structures, in particular a sensor chip, which determines a position or an angle by an incremental measurement, and a second sensor chip, which detects a magnetic reference mark.

In a preferred embodiment, a device for sensor signal processing or evaluation is provided either in the same package as the magnetic field-sensitive sensor or in the second package.

The manufacturing method according to the invention for producing an electrical component according to the invention provides that the encapsulation material of the first package is firmly connected to the encapsulation material of the second package.

In a particularly preferred embodiment, the following steps are provided as part of the production process:

 providing a first frame including a plurality of leadframes, wherein the chip is attached to at least one first leadframe and at least the first chip and at least a portion of the first leadframe are encapsulated by an encapsulation material and a first connection surface is formed on the encapsulation material;

 providing a second frame including a plurality of lead frames, wherein at least a part of a lead frame of the second frame is encapsulated by an encapsulating material and the second encapsulation surface is formed on the encapsulating material,

 mating the first connection surface with the second connection surface.

In a particularly preferred embodiment, the frames containing the plurality of leadframes have guides. For example, the frames may have holes at suitable locations, with which they can be plugged onto pins. By a suitable arrangement of the guides on the respective frame can be ensured when connecting the two frames that the two frames are brought together exactly in the relative position to each other, as desired for the creation of the electrical component according to the invention. In a particularly preferred embodiment, the provision of the first frame takes place in that the first frame having a guide is pushed onto a guide element, for example, is pushed onto a pin with holes provided in it. Subsequently, in a preferred embodiment, adhesive is applied to the first bonding surfaces of the first bonding surfaces

Assembled frame combined first package. Subsequently, the second frame with the connecting surfaces of the first packages facing connecting surfaces of the united in the second frame second packages with the provided in the second frame guide is pushed onto the guide means and also brought into contact with the adhesive. In a particularly preferred embodiment, the first packages and the second packages are pressed against each other during the curing of the adhesive. Subsequently, the individual electrical components are separated out of this sandwich, for example by means of sawing.

In a particularly preferred embodiment, the electrical components are tested at the end of the production.

The electrical component according to the invention has a printed circuit board and an electrical component connected to the printed circuit board. The connection of the electric

Component with the circuit board is particularly preferably via the connection of provided on the electrical component electrical connections with electrical connections to the circuit board. Particularly preferably, the connection of the terminals by means of soldering (eg reflow soldering). The printed circuit board is particularly preferably a solid printed circuit board. It can be made of fiber-reinforced plastic. However, it is also possible to use printed circuit boards made of Teflon, aluminum oxide, ceramic or flexible printed circuit boards, for example those made of polyester film, rigid-flex boards.

The invention will be explained in more detail with reference to exemplary embodiments closer illustrative drawing. Show:

Fig. 1: a perspective view of an electrical according to the invention

 component;

2 shows a first side view of a component according to the invention;

3 shows a plan view of a component according to the invention;

4 shows a further side view of a component according to the invention;

Fig. 5: another perspective view of an inventive

component; 6: a perspective top view of an inventive electrical

Component; 7 shows a perspective view of a first frame which is used in the production method according to the invention;

FIG. 8 shows the first frame according to FIG. 7 with adhesive applied to the connecting surfaces; FIG.

FIG. 9 shows the first frame with adhesive applied to it according to FIG. 8 and a second second frame placed upside down on the first frame; FIG. 10: the use of the component according to the invention as a path length sensor in a perspective plan view;

11 shows the use of the component according to the invention as a path length sensor in a perspective plan view;

12 shows the use of the component according to the invention as a path length sensor in a perspective plan view;

Fig. 13: a schematic representation of the structure of a magnetic field-sensitive sensor which is installed in the electrical component;

Fig. 14: a schematic representation of the structure of two magnetic field-sensitive sensors that can be installed in different packages of the electrical component.

The electrical component 1 according to the invention shown in FIGS. 1 to 5 has a first package 2 and a second package 3. The first package 2 has a first leadframe 4. At the first lead frame a not shown in the figures chip is attached. The first package includes encapsulation material 5 encapsulating the chip and at least portions of the leadframe 4. The second package 3 likewise has a connection frame 6, referred to here as a second connection frame. Furthermore, the second package 3 Encapsulation material 7, which encapsulates at least parts of the lead frame 6. Both the first package 2 and the second package 3 have a standardized design of a package, namely are designed as TDFN (Thin Dual Fiat no-Iead Package).

The first package has an underside 8 visible in the view of FIG. 2, an upper side 9 lying opposite the underside 8 and side surfaces 10, 11, 12, 13 connecting the upper side 9 and the lower side 8. The second package 3 has a comparable construction and has comparable surfaces. The surface 9 of the first package forms a first, planar connection surface. The comparable surface of the second package 3 forms a second, planar connecting surface. As can be seen in particular from FIGS. 1 and 3, the encapsulation material 5 of the first package 2 is firmly connected to the encapsulation material 7 of the second package 3. The first planar connection surface is glued to the second planar connection surface.

The first package has terminals 14. These are, as can be seen in FIGS. 1, 2 and 3, formed in the region of the edges of the first package. The side surface on which the respective terminal 14 is provided has four edges, namely an edge to the bottom 9, an edge to the top 8 and a first edge to a first further side surface and a second edge to a second, the first oppositely arranged further side surface. As can be seen in Figures 1, 2 and 3, the terminals are each formed in the region of one of these four edges of a side surface. The respective terminal 14 has a terminal surface which is partially in the surface of this page. In addition, the terminal 14 forms part of an edge. That is, a part of the edge is formed on the electric terminal 14. The electrical connection 14 has a partial surface, which is located in the surface of the page and a further partial surface, which is in the adjacent surface, so depending on the position of the edge in the surface of the bottom, the surface of the top or in the surface of a the adjacent other pages is located.

FIG. 6 shows the electrical component according to the invention in a perspective plan view. Evident is the circuit board 20 and the electrical component 1 according to the invention. The electrical component is connected to the side surface 13 with the printed circuit board 20. The connection is made by soldering to the terminals 14 at the edge to the side surface 13. Both the terminals 14 of the first package 2, as well as not visible in the view of Figure 6, comparable terminals of the second package 13 are soldered to terminals of the circuit board 20 , As on both sides of the electrical component. 1 Soldered connections are made, it is prevented that the upright electrical component 1 tilts to one side.

The production method according to the invention will be explained with reference to FIGS. 7 to 9.

As shown in Figure 7, first a first frame 21 is provided. This frame contains a plurality of lead frames. There is a chip attached to each lead frame. FIG. 7 shows the respective encapsulation material 5 of the packages 1 containing the respective lead frame and the respective chip. Since each package contains a print on its connection surface, the individual packages in the frame 21 in FIG. 7 can be easily recognized.

The frame 21 has holes 22. With these holes 22, the frame 21 is pushed onto fixing pins 23 and thus fixed in one position.

FIG. 8 illustrates that an adhesive 24 is applied to the first joining surfaces of the first packages.

FIG. 9 shows, for better illustration only with regard to the left part of the frame 21, that a second frame 25, which in its construction corresponds to the first frame 21, is also placed with its holes 22 on the fixing pins 23, namely - as in FIG apparent - over head. In this way, the second connecting surfaces of the second packages of the second frame 25 come into contact with the adhesive 24 and, after hardening of the adhesive 24, are firmly bonded by joining to the first connecting surfaces of the first packages of the first frame 21. During curing, the first frame 21 and the second frame 25 can be pressed against each other.

After curing of the adhesive 24, the electrical components 1 according to the invention are separated by sawing from the "sandwich" produced by gluing the first frame 21 together with the second frame 25. Thereafter, they can still be subjected to a functional test.

10 shows a perspective top view of an inventive electrical component 1 with a first package 2 and a second package 3. FIG. 10 also shows a pole strip 30. The pole strip 30 can be moved relative to the electrical component, either in which the pole strip 30 is fixed and the electrical component 1 is moved relative to the pole strip 30 or by the electrical component 1 is fixed and the pole strip 30 is moved or by both Polstreifen 30 and the electrical component 1 are moved, but with different high and / or different speeds.

The black area 31 in FIG. 10 clarifies that a magnetic-field-sensitive sensor is provided in the second package 3 in such a way that the sensitive sensor layer lies at the upper edge of the second package 3. The structure according to the invention of the electrical component 1 thus makes it possible to bring the magnetic field-sensitive layer particularly close to the pole strip 30 in relation to the printed circuit board 20 (not shown in FIG. 10).

The embodiment of FIG. 11 differs from that shown in FIG. 10 in that also in the first package 2 a magnetic field-sensitive sensor (black area 31) is arranged. In the embodiment of FIG. 11, this is identical to the magnetic-field-sensitive sensor in the second package 3, so that redundant measurements become possible.

The embodiment of FIG. 12 differs from that shown in FIG. 11 in that in the first package 2 a magnetic field-sensitive sensor (black area 31) is arranged, which is different from the magnetic field-sensitive sensor arranged in the second package 3. The magnetic-field-sensitive sensor provided in the second package 3 may be designed to fine-position the sensor, for example, to detect the position with a precision of 1 mm, while the sensor in the first package 2 has twice or more read widths for coarse positioning.

13 shows a schematic representation of the arrangement of the resistors 32 of a magnetoresistive sensor element in relation to the pole strip 30. FIG. 13 shows that in each case four resistors 32 are connected to one Wheatstone bridge in each case and that all the resistors 32 are arranged parallel to one another. Such an arrangement lends itself to the implementation of the design shown in FIG.

FIG. 14 illustrates the possibility of fulfilling different measuring tasks by using differently constructed magnetoresistive sensors in the packages. On the left in FIG. 14, the structure of a magnetoresistive sensor is shown, as is also known from FIG. This magnetoresistive sensor can be used as a path length sensor and be installed, for example, in the second package 3. The sensor shown on the right in FIG. 14 differs from that shown on the left in that the resistors 32 of the second Wheatstone bridge do not run parallel to the resistors 32 of the first Wheatstone bridge, but are rotated through 45 ° thereto. Such a sensor structure is suitable for determining a rotation angle. This magnetoresistive sensor could be used in the first package 2 be installed. As a result, with the use of two different magnetoresistive sensors with the electrical component according to the invention, both a path length sensor and a rotation angle sensor can be realized.

Claims

"Patent Claims:"

Electrical component (1).

a first package (2).

a first connection frame (4) and

a chip attached to the first connection frame (4) and encapsulation material (5), which covers the chip and at least parts of the connection frame

(4) encapsulated

marked by

a second package (3).

a second connection frame (6) and

Encapsulation material (7) that encapsulates at least parts of the connection frame (6).

wherein the encapsulation material (5) of the first package (2) is firmly connected to the encapsulation material (7) of the second package (3).

Electrical component according to claim 1, characterized in that on the encapsulation material

(5) of the first package (2) a first connection surface is formed and a second connection surface is formed on the encapsulation material (7) of the second package (3) and the first connection surface is connected to the second connection surface by joining.

Electrical component according to claim 2, characterized in that the chip is attached to a flat receiving surface of the first connection frame (4) on the first connection frame (4) and the first connection surface is designed parallel to the receiving surface of the first connection frame (4) and/or the second Connection frame (6) has a flat receiving surface for a chip and the second connection surface is designed parallel to the receiving surface of the second connection frame (6).

Electrical component according to one of claims 1 to 3, characterized in that the first package (2) has electrical connections (14) accessible from the outside and/or the second package (3) has electrical connections (14) accessible from the outside.

Electrical component according to one of claims 1 to 4, characterized in that the first package (2) is cuboid-shaped and/or the second package (3) is cuboid-shaped and/or the electrical component (1) is cuboid-shaped.

6. Electrical component according to claim 4 and 5, characterized in that the first package (2) is cuboid and an electrical connection (14) is formed in the area of an edge of the first package (2).

7. Electrical component according to one of claims 1 to 6, characterized in that a first flat connection surface is formed on the encapsulation material (5) of the first package (2) and a second plane on the encapsulation material (7) of the second package (3). Connection surface is formed and the first flat connection surface with the second flat connection surface

Joining is connected, wherein the connection frame (4) and the encapsulation material (5) of the first package are mirror-symmetrical with respect to the plane parallel to the first connection surface and the second connection surface and arranged centrally between the first connection surface and the second connection surface

Connection frame (6) and the encapsulation material (7) of the second package (3) are executed.

8. Electrical component according to one of claims 1 to 7, characterized in that the chip contains a magnetic field-sensitive sensor.

9. Electrical component according to claim 8, characterized in that the magnetic field-sensitive sensor uses the AMR, GMR or TMR effect.

10. Electrical component according to claim 9, characterized in that the magnetic field-sensitive sensor contains at least one Wheatstone bridge, which consists of several sensor elements distributed locally over the chip.

11. Electrical component according to one of claims 8 to 10, characterized by several magnetic field-sensitive sensors.

12. Electrical component according to claim 11, characterized in that the plurality of magnetic field-sensitive sensors are similar sensor chips.

13. Electrical component according to claim 1 1, characterized in that it has at least two different magnetic field-sensitive sensors.

14. Electrical component according to one of claims 8 to 13, characterized in that a device for sensor signal processing or evaluation is provided either in the same package as the magnetic field-sensitive sensor or in the second package.

15. Manufacturing method for producing an electrical component according to one of claims 1 to 14, characterized in that the encapsulation material (5) of the first package (2) is firmly connected to the encapsulation material (7) of the second package (3).

16. Manufacturing method according to claim 9, characterized by

- Providing a first frame (21) containing a plurality of connection frames (4), wherein the chip is attached to at least a first connection frame (4) and at least the first chip and at least a part of the first connection frame (4) are made of an encapsulation material (5) is encapsulated and a first connecting surface is formed on the encapsulation material (5),

- Providing a second frame (25) containing a plurality of connection frames, wherein at least part of a connection frame (6) of the second frame is encapsulated by an encapsulation material (7) and a second connection surface is formed on the encapsulation material (7). joining the first connection surface to the second connection surface.

17. Electrical component with a circuit board (20) and an electrical component (1) connected to the circuit board (20) according to one of claims 1 to 14.

18. Electrical component according to claim 17, characterized in that the electrical component (1) is cuboid and has a top (8) and a bottom (9) opposite the top (8) and side surfaces (10, 11, 12, 13) and the electrical component (1) is connected to the circuit board (20) with one of the side surfaces (10, 11, 12, 13) facing the circuit board (20).