KR101804579B1 - Inputting device - Google Patents

Abstract

The present invention provides a magnetic shielding layer that does not affect the operation of a geomagnetic sensor in a touch-screen pointing input device through an electromagnetic pen. To this end, the magnetic shielding layer according to the present invention is made of a magnetic powder material. This magnetic shielding layer can be formed directly on the pointing input device without a separate adhesive layer.

Description

[0001] INPUTING DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pointing input device, and more particularly to a pointing input device having a magnetic shielding layer for allowing an Earth's magnetic field sensed by a geomagnetic sensor to be transmitted.

In recent years, as the market for smart phones or touch screens has grown rapidly, related research has also been actively conducted. A touch screen is widely used as an input device of such a mobile terminal. The touch screen usually consists of a transparent electrode. Capacitive type touch screens, which measure changes in capacitance caused by touches, are often used. However, the electrostatic capacity type touch screen has a disadvantage that the user must provide a predetermined pressure or displacement by performing contact with the touch screen at any time, and input using a pen is not possible.

In order to overcome these disadvantages, touch screen technology using electromagnetic wave has recently been widely used. An example of a pointing input device of this type is a pointing input device of an electromagnetic resonance (EMR) type.

However, in an electronic device such as a mobile terminal as described above, an apparatus for mounting a pointing input device, a battery, various circuit parts, and the like are disposed, which may cause magnetic field blocking and disturbance. Therefore, since the performance of the pointing input device is adversely affected, a magnetic shielding layer is used to prevent this.

On the other hand, the mobile terminal employs various additional functions in order to enhance convenience of use and entertainment fun. As an example of such a case, there is a function that the screen changes according to the degree of motion of the mobile terminal. To detect such movement, a geomagnetic sensor is mounted on the mobile terminal. However, when such a geomagnetic sensor is to be provided in the pointing input device, the operation of the geomagnetic sensor will be influenced by the existence of the magnetic shielding layer.

In addition to the geomagnetic sensor, parts having strong magnets such as speakers and cameras are also mounted on the mobile terminal. Since these magnet parts generate a strong low frequency magnetic field, a magnetic shielding layer considering this is required.

As described above, the magnetic-field shielding layer does not induce an eddy current, and the position of the electromagnetic pen can be accurately tracked. However, when the geomagnetic sensor is disposed near the magnetic shielding layer, the low-frequency magnetic field such as the Earth's Magnetic Field is blocked or distorted by the magnetic shielding layer, which makes it difficult to operate the geomagnetic sensor accurately.

Accordingly, magnetic fields generated by an apparatus, a battery, various circuit parts, and the like disposed below the magnetic shielding layer are blocked, thereby preventing the magnetic field from being attenuated. In addition, the magnetic field sensed by the geomagnetic sensor is transmitted so that the magnetic field shielding Layer is required. When a pointing input device including a mobile terminal is equipped with a magnetic component, a strong low-frequency magnetic field signal generated by the magnet components is effectively blocked, and a low-frequency magnetic field to ensure the operation of the geomagnetic sensor is transmitted. A shielding layer is required.

Accordingly, the present invention provides a pointing input device having a magnetic shielding layer that does not affect the operation of the geomagnetic sensor.

The present invention also provides a pointing input device having a magnetic shielding layer that can partially transmit a magnetic field applied to a geomagnetism sensor so as to detect a geomagnetic field.

The present invention also provides a pointing input device having a magnetic shielding layer capable of sensing magnetic field in a geomagnetic sensor and effectively shielding magnetic field signals generated by magnet components.

According to an aspect of the present invention, there is provided an electronic pen comprising: a display unit for outputting a display screen; an electromagnetic sensing unit disposed at a lower portion of the display unit and sensing a magnetic field generated from an electromagnetic pen, A magnetic field portion shielding layer disposed on the lower portion of the electromagnetic sensing portion, and a geomagnetic sensor for sensing a magnetic field applied via the magnetic field portion shielding layer.

The magnetic shielding layer according to the present invention can minimize the influence on the operation of the geomagnetic sensor installed in the pointing input device while preventing the magnetic field generated by the electromagnetic pen from reaching the pointing input device even if the conductor is provided under the magnetic shielding layer .

Further, by using the magnetic substance powder in the magnetic shielding layer according to the present invention, it is possible to form a magnetic shielding layer directly on the pointing input device without a separate adhesive layer, so that the thickness of the pointing input device can be reduced.

In addition, in the present invention, it is possible to maximize the sensitivity while minimizing the influence on the geomagnetic sensor through the use of different magnetic powder powders.

In the present invention, a magnetic shielding layer having a low magnetic shielding property such as a powder magnetic material and a magnetic shielding layer having a high shielding property such as an amorphous metal are disposed in consideration of the positions of the geomagnetic sensor, the speaker and the camera, The performance and the performance of the pointing input device can be guaranteed.

1 is a schematic view showing a cross section of a pointing input device having a magnetic shielding layer according to an embodiment of the present invention;
2 is a diagram for explaining magnetic field cancellation by an eddy current,
3 is a cross-sectional view of a pointing input device according to a comparative example,
FIG. 4 is a graph showing the characteristics of a magnetic field sensor using a conventional amorphous metal,
FIG. 5 is a graph showing the magnetic permeability characteristic for each amorphous metal frequency,
6 is a graph showing permeability-specific permeability characteristics for amorphous metal and magnetic powder,
FIG. 7 is a cross-sectional view illustrating a configuration in which a magnetic shield layer according to an embodiment of the present invention is disposed; FIG.
FIG. 8 is a layout view for explaining a configuration in which a magnetic shield layer according to another embodiment of the present invention is disposed;
FIG. 9 is a sectional view of FIG. 8,
10 is a graph showing characteristics of a geomagnetic sensor when a magnetic powder material is used according to an embodiment of the present invention,
11 is a graph showing a comparison of sensitivity when an amorphous metal and a magnetic powder having a permeability of 150 are used according to an embodiment of the present invention,
FIG. 12 is a cross-sectional view illustrating a configuration in which a magnetic shield layer according to another embodiment of the present invention is disposed. FIG.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be noted that the same components in the drawings are denoted by the same reference numerals whenever possible. In the following description and drawings, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention unnecessarily obscure.

The present invention provides a magnetic shielding layer that does not affect the operation of a geomagnetic sensor in a touch-screen pointing input device through an electromagnetic pen. For this purpose, the magnetic shielding layer according to the present invention is made of a magnetic powder material. The magnetic shielding layer can be formed directly on the pointing input device without a separate adhesive layer by mixing the magnetic substance powder and the adhesive and applying the same.

Before describing the present invention, the operation principle of the electromagnetic resonance pointing input device used in the present invention will be briefly described. Such a pointing input device has a touch screen.

1, in the electromagnetic resonance method, a loop coil 110 is disposed in an electromagnetic sensing unit 115, a current is conducted to control a magnetic field to be generated, and a generated magnetic field is applied to the electromagnetic pen 102, To be absorbed. Here, the electromagnetic pen 102 may include a capacitor 100 and a coil 105, and may discharge the absorbed magnetic field again at a predetermined frequency.

The magnetic field emitted by the electromagnetic pen 102 may be absorbed again by the loop coil 110 of the electromagnetic sensing portion 115 so that the electromagnetic pen 102 is in close proximity to the position of the pointing input device Can be determined.

The electromagnetic sensing unit 115 includes a plurality of loop coils 110 that interact with the electromagnetic pen 102. The plurality of loop coils 110 are overlapped with each other. If the user brings the electromagnetic pen 102 close to a specific portion, the plurality of loop coils 110 can sense the magnetic field generated from the electromagnetic pen 102. [ Accordingly, each of the plurality of loop coils 110 outputs an induced current induced by the sensed magnetic field. The closer the loop is to the electromagnetic pen 102 among the plurality of loop coils 110 of the electromagnetic sensing unit 115, the higher the amplitude of the magnetic field can be sensed and the corresponding induced current can be emitted. Accordingly, the plurality of loop coils 110 can output induction currents of various sizes, so that the position of the electromagnetic pen 102 can be tracked if the output of the loop coils 110 is measured.

Meanwhile, a magnetic shielding layer 120 is provided under the electromagnetic sensing part 115. A lower surface of the magnetic shielding layer 120 is provided with a printed circuit board unit 130 on which an apparatus for firmly mounting a pointing input device, a battery, various circuit parts, and the like are disposed. The magnetic shielding layer 120 serves to cut off the magnetic field so that the magnetic field is not attenuated due to the magnetic field generated from the circuit portion or the like disposed on the printed circuit board portion 130 placed under the magnetic shielding layer 120.

The principle of the magnetic shielding layer will be briefly described below with reference to FIG. Fig. 2 is a diagram illustrating a case where a magnetic field is applied to a metal having a low resistance without a magnetic shielding layer. When a magnetic field is applied to a material with low electrical resistance, an eddy current is generated. The eddy current generates a magnetic field in the opposite direction of the applied coil magnetic field to generate an eddy current magnetic field, which results in the eddy current magnetic field and the coil magnetic field canceling each other. Therefore, when the magnetic field is reduced, the recognizable distance from the electromagnetic pen 102 is shortened, thereby increasing the possibility of malfunction.

To prevent this, a magnetic shielding layer 120 is used. In this case, since the coil magnetic field does not reach the lower portion of the magnetic shielding layer 120, eddy currents are not generated even if a conductor is provided in the lower portion, so that the magnetic field is not attenuated. Accordingly, the coil magnetic field reaches only the electromagnetic sensing portion 115 which is in contact with the magnetic-field shielding layer 120 without magnetic field attenuation, so that the magnetic field induced by the electromagnetic pen 102 can be sensed.

Generally, an alloy thin film containing silicon (Si) based on iron (Fe) is used as a magnetic shielding layer for such a pointing input device. In recent years, amorphous metals have been used in which iron (Fe), silicon (Si), and boron (B) are mixed and the crystal structure is removed. The amorphous metal is a material having a high magnetic permeability to a magnetic field in a frequency band of several hundred kHz and a magnetic field shielding performance because of high conductivity, which is commonly used in a pointing input device. In particular, amorphous metals have a much higher permeability in DC than other materials.

However, when the geomagnetic sensor 125 is located close to the magnetic field shielding layer made of amorphous metal, as shown in FIG. 3, the magnetic field sensed by the geomagnetic sensor 125 is blocked by the magnetic shielding layer 120 It can be distorted. In other words, it becomes difficult to operate the geomagnetic sensor 125 that detects the geomagnetic field, which is a DC magnetic field, due to the amorphous metal 120 having high permeability in DC.

The results of evaluating the characteristics of the geomagnetic sensor when such an amorphous metal is used are shown in Fig. The graph in FIG. 4 illustrates the output of the geomagnetic sensor when the DC magnetic field is rotated around the geomagnetic sensor. The direction of the magnetic field applied is determined by the ratio of each direction component of the geomagnetism sensor output, that is, the ratio of the x- and y-direction outputs of the graph. Therefore, in a geomagnetic sensor, both axis directions must have the same sensitivity with respect to the magnetic field direction in order to obtain an accurate magnetic field direction. For example, if a magnetic field is applied in the direction of 45 degrees, the intensity of the magnetic field measured on each axis must be the same.

Therefore, if a magnetic field of a certain magnitude is applied to all directions while the geomagnetism sensor is operating normally, if the magnitude of the magnetic field in both directions increases by one as shown in FIG. 4 (a) Has a constant shape, i.e., a circle.

In contrast, in the case where a magnetic body is present in the vicinity of the geomagnetic sensor, the circle in FIG. 4 (a) has the shape of an ellipse that moves in the center or is not a circle as shown in FIG. 4 (b). The graph in Fig. 4 (b) means that the geomagnetic sensor malfunctions due to geomagnetic interception and disturbance of the amorphous metal. In addition, the amorphous metal retains the magnetization when a large magnetic field is applied due to a large residual magnetic field, and thus acts as a permanent magnet. Thus, the influence on the geomagnetic sensor can be continuously maintained.

Referring to FIG. 5 showing the characteristics of the amorphous metal with frequency-specific permeability, FIG. 5 shows that the permeability is 1000 or more in a frequency band of 100k or less. This means that the effect on the geomagnetic sensor is very large.

Therefore, a pointing input device having a function of sensing a magnetic field such as a geomagnetic sensor requires a magnetic shielding layer capable of simultaneously shielding the magnetic field without affecting the geomagnetic sensor.

In consideration of this, the present invention proposes a magnetic shielding layer made of a magnetic material powder material. 6, the amorphous metal has a permeability of 170 or more in the 500 KHz band and a permeability of 10000 or more as shown in FIG. 5 below. In this case, the geomagnetic field sensed by the geomagnetic sensor is blocked or distorted by the amorphous metal, making it impossible to operate the geomagnetic sensor.

On the other hand, the magnetic material powder material used in the present invention has a magnetic permeability of 100 in the 500 KHz band, and this permeability is maintained over a wide frequency range. In addition, the permeability in the DC band is similar. Therefore, compared with the case where the DC permeability of the amorphous metal is more than 10,000, the permeability of the magnetic material powder is about 1/100, which shows that the influence on the geomagnetic sensor can be minimized compared with the amorphous metal.

Here, although the magnetic permeability in the use band of 500 KHz is exemplified as 100, the magnetic shielding layer can be constituted so that the magnetic permeability is 150 by using the magnetic material powder material. In this case, it is possible to cut off the magnetic field induced by the electromagnetic pen since the magnetic permeability is similar to that in the case of using the amorphous metal in the mainly used band without significantly affecting the performance of the pointing input device. Furthermore, the permeability of the magnetic powder material is maintained at a relatively low permeability over a wide frequency range, so that the magnetic field detected by the geomagnetic sensor is transparent.

Hereinafter, referring to FIG. 7, a description will be given of a configuration in which a magnetic shielding layer composed of a magnetic powder material as described above is disposed according to an embodiment of the present invention.

7 illustrates a cross-sectional view of the pointing input device of FIG. 1 wherein the pointing input device includes a display portion 700, an electromagnetic sensing portion 115, a magnetic shielding layer 120, a geomagnetic sensor 125, 130).

First, the display unit 700 is an area for displaying visual information that can be recognized by the user. The display unit 700 receives a control signal or a graphic signal from the outside, and can output a display screen corresponding to the control signal or the graphic signal. The display unit 700 may preferably be a liquid crystal display (LCD) module, but it will be readily understood by those skilled in the art that the display unit 700 is not limited.

The electromagnetic sensing unit 115 may be disposed adjacent to a lower surface of the display unit 700. [ The detailed configuration of the electromagnetic sensing unit 115 is the same as that described with reference to Fig. The electromagnetic sensing unit 115 senses electromagnetic waves incident on the upper portion of the display unit 700 or from the contacted electromagnetic pen to determine which point the user has designated.

The geomagnetic sensor 125 is arranged in this pointing input device and senses a magnetic field applied via the magnetic shielding layer 120. [ The geomagnetic sensor 125 may be located below the magnetic shielding layer 120 that is not affected by the magnetic field from the electromagnetic pen. As another example of this arrangement, the geomagnetic sensor 125 may be mounted on the printed circuit board portion 130 ). ≪ / RTI >

The printed circuit board unit 130 includes various electronic components and the like that can electrically operate and control the pointing input device. The magnetic field including electromagnetic waves generated from various electronic components of the printed circuit board unit 130 is blocked by the magnetic shielding layer 120 made of the magnetic powder material.

The magnetic shielding layer 120 of the present invention is composed of a magnetic powder material and is disposed under the electromagnetic sensing part 115. The magnetic shielding layer 120 is a partially shielding layer that can partially transmit the applied magnetic field, and is formed by scattering the magnetic powder. As the magnetic powder, magnetic metal powders such as ferrite, molypermalloy powder, Fe-Si-Al based material and Ni-Fe based material may be used. Since the magnetic powder has a powdery form, unlike the case of using a metal, it can be spread by mixing with an adhesive such as a polymer. In addition to these powders, an amorphous metal powder may also be used, and the magnetic metal powder and the amorphous metal powder may be mixed together with the adhesive to form the magnetic shielding layer 120.

As described above, the magnetic shielding layer 120 made of the magnetic powder varies in magnetic permeability depending on the density of the magnetic powder. When the density of the magnetic powder is increased, the magnetic permeability is increased. In addition, since the powder is used, the magnetic shielding layer 120 can be mixed with the magnetic metal powder and mixed with the amorphous metal powder. Accordingly, it is possible to make the density of the magnetic material powder of the magnetic shielding layer 120 so as to obtain a permeability similar to that of the metal thin film. Unlike the metal thin film, the magnetic field can be transmitted, It will not go crazy.

At this time, the magnetic permeability of the magnetic shielding layer 120 according to the embodiment of the present invention is such that the density is 100 to 200 or less in the DC band It is preferable to be determined. Thus, the output characteristic of the geomagnetic sensor as shown in FIG. 10 can be obtained, which is similar to that shown in FIG. 4 (a), which shows the output characteristic of the geomagnetic sensor when there is no amorphous metal. That is, when the magnetic substance powder material is used, the geomagnetic sensor operates normally.

In addition, since the magnetic powder is mixed with the adhesive, the magnetic powder is adhered to the electromagnetic sensing part 115 in a form to be applied. Accordingly, the adhesive layer can be omitted as compared with the conventional magnetic shielding layer in which the metal thin film is adhered after applying the adhesive, so that the thickness can be reduced. In other words, when the magnetic powder material is mixed with an adhesive, it has a liquid form and can be evenly applied through a coating method or the like. As described above, since it is possible to apply uniformly differently from the case of using a conventional metal thin film, the shielding performance can exhibit uniform quality over the entire surface of the magnetic shielding layer 120. In addition, the magnetic shielding layer 120 can be directly bonded to the pointing input device without a separate adhesive layer, so that the process is simplified and an allowable thickness corresponding to the thickness of the existing adhesive layer is secured.

As described above, the magnetic material powder material may be coated on one surface of the pointing input device, for example, the electromagnetic sensing part 115, or may be coated on an adhesive film having adhesive force and then adhered to one surface of the pointing input device.

Unlike the amorphous metal thin film, the magnetic material powder does not have a large residual magnetic field and does not affect the operation of the geomagnetic sensor even when a large magnetic field is applied. However, when the pointing input device having the magnetic shielding layer 120 using the magnetic powder material is placed on a magnetic field decoupler such as a conductor, the sensitivity may deteriorate due to the influence of the eddy current, the generation of the magnetic field, have. However, this sensitivity degradation is only relative to the amorphous metal thin film, and has a suitable level of sensitivity for the pointing input device as shown in FIG.

FIG. 11 is a graph showing sensitivity comparison between a magnetic powder material and an amorphous metal thin film according to an embodiment of the present invention. FIG. 11 is a graph illustrating sensitivity of a magnetic material powder material having a magnetic permeability of 150 and a thickness of 50 .mu.m and an amorphous metal thin film having a thickness of 25 .mu.m The signal intensity of the signal is measured. As shown in FIG. 11, the magnetic material powder may have a lower sensitivity than an amorphous metal thin film. However, in order to obtain a desired sensitivity, it is possible to adjust the sensitivity through elasticity of thickness control according to the situation. The thickness of the magnetic shielding layer 120 according to the embodiment of the present invention is preferably 50 占 퐉 or more. Since this thickness depends on the magnetic permeability of the magnetic shielding layer, the thickness can be determined as the permeability is fixed.

According to another embodiment of the present invention, the magnetic shielding layer may be configured as shown in FIG. In FIG. 8, a magnetic shielding layer 805 using a magnetic powder is disposed around the geomagnetic sensor 800, and a magnetic shielding layer 810 using an amorphous metal thin film is positioned in the vicinity of the magnetic shielding layer 805. For example, when the geomagnetic sensor 800 is located at the center, the magnetic field shielding layer 805 using the magnetic powder material is disposed around the geomagnetic sensor 800 so that the operation of the geomagnetic sensor 800 And the sensitivity is improved by arranging the amorphous metal magnetic shielding layer 810 in the remaining area.

The arrangement as shown in Fig. 9 is also possible. FIG. 9 illustrates an arrangement of a magnetic shielding layer 805 using the magnetic powder and a magnetic shielding layer 810 using the amorphous metal thin film. The magnetic-field shielding layer is composed of a magnetic powder shielding layer 805 on which a magnetic powder that partially permeates the applied magnetic field is scattered, and a shielding layer 810 using an amorphous metal thin film that blocks the rest of the applied magnetic field. The positions of the magnetic shielding layer 805 using the magnetic powder and the magnetic shielding layer 810 using the amorphous metal thin film may be changed according to the position of the geomagnetic sensor 800 as shown in FIG.

8 and 9, the magnetic shielding layer 805 may be formed of a magnetic material powder corresponding to the position of the geomagnetic sensor 800 in the entire magnetic shielding layer will be. By using such a magnetic material powder, it is possible to restrict the transmission of a magnetic field of a frequency used for pointing while allowing the magnetic field of a low frequency such as a magnetic field sensed by the geomagnetic sensor 800 to be transmitted well. However, the amorphous metal magnetic shielding layer 810 is formed in the remaining portion to shield the magnetic field generated by the arrangement of the pointing input device, the battery, and various circuit parts.

However, since the amorphous metal magnetic-field-shielding layer 810 is formed outside the region of the magnetic powder magnetic-field-shielding layer 805 as shown in FIGS. 8 and 9, The performance of the geomagnetic sensor 800 may be somewhat deteriorated as compared with the structure of the magnetic window shielding layer in FIG. For example, in FIG. 7 according to an embodiment of the present invention, since the entire magnetic shielding layer is formed of the magnetic powder magnetic shielding layer 120 regardless of the position of the geomagnetic sensor 125, the magnetic powder magnetic shielding layer 120, Does not block the earth magnetic system and does not affect the performance of the geomagnetic sensor 125.

Accordingly, another embodiment of the present invention proposes a magnetic shielding layer structure as shown in FIG. In particular, another embodiment of the present invention proposes a magnetic shielding layer structure considering a case where a magnetic part for generating a strong low-frequency magnetic field is mounted in addition to a geomagnetic sensor.

In FIG. 12, there is illustrated a case where a speaker, a camera, or the like is mounted on one side of the printed circuit board unit 130 as an example of such a magnet unit, but such a magnet unit can also be placed on the printed circuit board unit 130. The magnetic field generated in such a magnet component can penetrate the magnetic powder magnetic shielding layer and affect the performance of the pointing input device. For example, in the case of an electromagnetic wave system, a magnetic field generated by a magnet component can change the frequency and intensity of a signal generated in the pen, thereby disturbing operation. However, if a magnetic shielding layer having a good shielding property such as an amorphous metal for shielding a magnetic field generated in such a magnet part replaces the magnetic powder magnetic shielding layer 120 in FIG. 7, such an amorphous metal magnetic shielding layer may be a geomagnetic sensor 125) is affected.

Therefore, in another embodiment of the present invention, a structure is proposed in which the magnetic field generated in the magnet component is effectively blocked while the performance of the geomagnetic sensor 800 is not influenced in consideration of this point.

The structure of the magnetic shielding layer of FIG. 12 is similar to that of the magnetic shielding layer of FIG. 7 except that a magnetic component, for example, a speaker, which generates a strong low frequency magnetic field under the magnetic powder magnetic shielding layer 1210, , And that the amorphous metal magnetic shielding layer 1220 is disposed near the camera 1230. The amorphous metal magnetic shielding layer 1220 is disposed below the magnetic powder magnetic shielding layer 1210 formed on the entire surface of the electromagnetic sensing part 115 and is in close contact with the magnetic powder magnetic shielding layer 1210, 1230). At this time, the amorphous metal magnetic-field-shielding layer 1220 is disposed in close contact with a part of the surface of the magnetic powder magnetic-field-shielding layer 1210, not the entire surface thereof, Therefore, it may vary depending on the size and arrangement position of the magnet parts.

Claims (14)

A display unit for outputting a display screen,
An electromagnetic sensing unit disposed below the display unit for sensing a magnetic field generated by an electromagnetic pen outside the input device,
A shielding layer formed on a lower surface of the electromagnetic sensing part to shield at least a part of the magnetic field,
And a geomagnetic sensor disposed below at least a portion of the shielding layer for sensing a geomagnetic field passing through the shielding layer.
The method according to claim 1,
And the magnetic material and the adhesive are mixed and applied.
The method according to claim 1,
Wherein the permeability has a density of 100 to 200 or less in the DC band.
The method according to claim 1,
Wherein the thickness is 50 占 퐉 or more, and the thickness varies depending on the permeability of the shielding layer.
The magnetic material according to claim 1, wherein the magnetic material comprises a magnetic powder, and the magnetic material is selected from the group consisting of ferrite, molypermalloy powder (MPP), Fe-Si-Al series material and Ni- Wherein the magnetic metal powder is a magnetic metal powder.
6. The semiconductor device according to claim 5,
And the magnetic metal powder and the amorphous metal powder are mixed together with an adhesive.
The method according to claim 1,
And the second electrode is formed on the lower surface of the electromagnetic sensing part.
The method according to claim 1,
Further comprising a printed circuit board portion disposed below the shielding layer and on which the geomagnetic sensor is disposed.
[10] The method of claim 8, wherein when the magnet component is disposed on the printed circuit board,
Further comprising a shielding layer using a thin film of amorphous metal at a position adjacent to the magnet component and below the shielding layer.
10. The method of claim 9,
Wherein the shielding layer is formed on one side of the electromagnetic sensing part and the shielding layer using the amorphous metal thin film is disposed on a part of the shielding layer.
10. The magnetic element according to claim 9,
A speaker, and a camera.
The method according to claim 1,
And a shielding layer using an amorphous metal thin film which shields the rest of the applied magnetic field, and a shielding layer using an amorphous metal thin film that shields the rest of the applied magnetic field.
13. The method according to claim 12, wherein the magnetic powder shielding layer and the shielding layer using the amorphous metal thin film are disposed at positions,
Wherein the position of the geomagnetic sensor varies depending on the position of the geomagnetic sensor.
13. The input device according to claim 12, wherein the magnetic powder shielding layer is disposed around the geomagnetic sensor, and a shielding layer using the amorphous metal thin film is disposed in a region other than the region where the magnetic powder shielding layer is disposed.

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