KR102230167B1 - The transparent antenna with glasses and design of reducing sar effect - Google Patents

Abstract

In the present invention, the antenna of the existing Google Glass was not of a glasses-attached type, but a built-in type of glasses, and was not transparent, so that an antenna could not be formed on the spectacle lens. Considering the antenna beam pattern, the beam radiation is radiated to the head of the human body. In order to improve the problem that is greatly affected by electromagnetic waves, it is composed of a ground part 100 and a transparent antenna part 200, so that the antenna can be made transparent through a transparent and conductive multi-layered thin film using a transparent electrode element. In addition, by forming a transparent antenna in an unobtrusive position, the effect can be minimized so that the field of view is not obstructed, and the effect of SAR (Specific Absorption Rate) can be reduced by 80% compared to the previous one by considering the antenna beam pattern, and ultra-high frequency communication Free communication is possible by attaching a possible small antenna to the eyeglass lens, and it is compatible with the field of wireless communication devices and electronic devices (mobile phones, smartphones, automobiles, GPS receivers, EM sensors) through the production of transparent antennas and beam steering control. The purpose of this is to provide a transparent antenna module with glasses that can be applied and a method for reducing SAR through the same.

Description

Glasses-attached transparent antenna module and method of reducing SAR through it {THE TRANSPARENT ANTENNA WITH GLASSES AND DESIGN OF REDUCING SAR EFFECT}

The present invention is a technology for using glasses such as Google Glass for the original purpose of the glasses, but also for utilizing the communication Internet through wireless signals. It relates to a glasses-attached transparent antenna module to reduce the reduction and SAR reduction formation method through the same.

The recently developed Google Glass supports wireless communication and requires an antenna for communication.

The antenna of the existing Google Glass was a built-in type of glasses rather than an attached type of glasses, and there was a problem that an antenna could not be formed on the spectacle lens because it was not transparent.

In addition, when the antenna beam pattern is considered, there is a problem that the beam radiation is radiated to the head of the human body, so that the human body is greatly influenced by electromagnetic waves.

1. Korean Patent Publication No. 10-2011-0092638 2. Korean Patent Publication No. 10-2012-0101487

In order to solve the above problems, in the present invention, the antenna can be transparently manufactured through a multilayered thin film having a transparent and good conductivity by using a transparent electrode element, and a transparent antenna is formed in an unobtrusive position so that the view is not obstructed. The effect can be minimized, the effect of SAR (Specific Absorption Rate) can be reduced than before by considering the antenna beam pattern, and a small antenna capable of ultra-high frequency communication can be attached to the spectacle lens for free communication, and a transparent antenna is manufactured. Provides glasses-attached transparent antenna modules that can be compatible and applied to mass production of wireless communication devices and electronic devices (cell phones, smartphones, automobiles, GPS receivers, EM sensors) through beam steering control and SAR reduction formation method through the same. It has its purpose.

In order to achieve the above object, the glasses-mounted transparent antenna module according to the present invention

A ground part 100 to ground the spectacle lens rim to one side of the spectacle lens rim in contact with the pupil and the spectacle frame to be in contact with the temple,

A transparent electrode formed by stacking any one or more of an IZTO (Indium Zinc Tin Oxide) transparent electrode element and an Ag transparent electrode element in a multi-layered structure is formed at one side of the front end of the ground part 100 to form a transparent antenna. It is achieved by being configured with the antenna unit 200.

In addition, the SAR reduction formation method through the glasses-attached transparent antenna module according to the present invention

A step (S300) of forming a "p"-shaped transparent antenna by forming the ground part 100 and the transparent antenna part 200 on one side of the upper end of the spectacle frame connected to the spectacle lens,

Third, the horizontal upper edge of the spectacle lens edge connected to the spectacle frame is set as the x-axis, the vertical side rim of the spectacle lens edge connected to the spectacle frame is set as the y-axis, and the position on the same line with the spectacle frame is set as the z-axis. xyz axis setting step (S310),

Through the 3rd SAR-reduced beam steering mode, the beam radiation direction directed from the "ㅏ"-shaped transparent antenna module is directed from the yz-axis to the z-axis and the z-axis to be in contact with the eyes and temples of the human body. This is achieved by performing the SAR reduction type antenna beam forming step (S320) of forming an antenna beam in a direction opposite to the human body contact with respect to the ground.

As described above, in the present invention, the antenna can be transparently manufactured through a multi-layered thin film having a transparent and good conductivity using a transparent electrode element, and the light transmittance to the antenna is 85% or more so that it is not unobtrusive. By forming a transparent antenna, the effect can be minimized so as not to obscure the field of view, and the effect of SAR (Specific Absorption Rate) can be reduced by 80% compared to the previous one by considering the antenna beam pattern. It has a good effect that can be widely applied to the field of devices (cell phones, smartphones, automobiles, GPS receivers, EM sensors).

1 is a configuration diagram showing the components of the glasses-mounted transparent antenna module 1 according to the present invention,
Figure 2 is a block diagram showing the components of the transparent antenna unit according to the present invention,
3 is one of the "L"-shaped transparent antenna module 1a, the "b"-shaped transparent antenna module 1b, and the "ㅏ"-shaped transparent antenna module 1c according to the present invention. A configuration diagram showing what has been selected and made,
Figure 4 is an embodiment showing the shape of the "L"-shaped transparent antenna module (1a) according to the present invention,
Figure 5 is an embodiment showing the shape of the "a"-shaped transparent antenna module (1b) according to the present invention,
Figure 6 is an embodiment showing the shape of the "ㅏ"-shaped transparent antenna module (1c) according to the present invention,
7 is an exemplary diagram showing a beam pattern structure of an antenna designed in a design method to reduce the effect of SAR in consideration of beam radiation to the "k"-shaped transparent antenna module 1c according to the present invention;
8 is an exemplary diagram showing that the transparent antenna unit according to the present invention is formed in a three-layer structure of IZTO/Ag/IZTO;
FIG. 9 is a flow chart showing a method for reducing SAR formation of a transparent antenna module having a "a" shape through the first SAR reduction beam steering mode 210 according to the present invention;
10 is a flow chart showing a method for reducing SAR formation of a transparent antenna module having an "L" shape through the second SAR reduction beam steering mode 220 according to the present invention;
11 is a flow chart illustrating a method for reducing SAR formation of a transparent antenna module having a "ㅏ" shape through the third SAR reduction beam steering mode 230 according to the present invention.

Hereinafter, a preferred embodiment according to the present invention will be described.

1 is a configuration diagram showing the components of the glasses-mounted transparent antenna module 1 according to the present invention, which is composed of a ground part 100 and a transparent antenna part 200.

First, the ground unit 100 according to the present invention will be described.

The ground part 100 serves to ground the spectacle lens to one side of the spectacle lens rim in contact with the pupil and the spectacle frame in contact with the temple.

This is configured to keep a part of the circuit in contact with the human body to maintain the zero potential.

At this time, the beam radiation direction is formed in a structure of an upward radiation pattern based on the ground in contact with the pupils and temples of the human body.

The ground part 100 is made of a transparent flexible polyamide substrate, and an adhesive is applied to the bottom of the transparent flexible polyamide substrate to adhere to one side of the eyeglass frame and one side of the eyeglass frame.

Next, the transparent antenna unit 200 according to the present invention will be described.

The transparent antenna part 200 is located at one side of the front end of the ground part 100, and includes a transparent electrode formed by stacking at least one of an IZTO (Indium Zinc Tin Oxide) transparent electrode device and an Ag transparent electrode device in a multilayer structure. It serves to form a transparent antenna by making it thin.

It is formed as a transparent antenna pattern made of any one of a square, a triangle, a circular patch shape, and a loop shape.

As shown in FIG. 8, the transparent antenna part is formed with an IZTO (Indium Zinc Tin Oxide) transparent electrode element as a first layer on a transparent flexible polyamide substrate, and an Ag transparent electrode element as a second layer on the first layer. In addition, an IZTO (Indium Zinc Tin Oxide) transparent electrode element is formed as a third layer on the second layer, and has a three-layer structure of IZTO/Ag/IZTO.

As such, the transparent antenna portion is formed in a three-layer structure of IZTO/Ag/IZTO, thereby forming a flexible transparent antenna portion that is transparent and has high flexibility and transmittance.

As shown in FIG. 2, the transparent antenna unit 200 has a first SAR reduction beam steering mode 210, a second SAR reduction beam steering mode 220, and a third SAR reduction beam steering mode on one side. Any one of 230 is selected and configured.

The first SAR reduction type beam steering mode 210 is such that the beam radiation direction directed from the "a"-shaped transparent antenna module is oriented on the xy axis with respect to the x axis and in the same way as on the x axis, so that the pupils and temples of the human body It serves to form an antenna beam in the opposite direction of the human body contact based on the ground contacted with.

This sets the horizontal upper edge of the edge of the spectacle lens connected to the spectacle frame as the x-axis, the vertical lateral edge of the spectacle frame and the edge of the spectacle lens is set as the y-axis, and the position on the same line as the spectacle frame is set as the z-axis.

And, the y-axis refers to the axis located in the z-axis and 90° direction.

The second SAR reduction type beam steering mode 220 turns off the first beam steering switch in accordance with the reference beam signal table and turns off the second beam steering switch to form an "L"-shaped transparent antenna module. It plays a role of forming an antenna beam in the opposite direction of human body contact based on the ground in contact with the pupils and temples of the human body by making the beam radiation direction directed from the xy axis to the y axis and the y axis. .

This sets the horizontal upper edge of the edge of the spectacle lens connected to the spectacle frame as the x-axis, the vertical lateral edge of the spectacle frame and the edge of the spectacle lens is set as the y-axis, and the position on the same line as the spectacle frame is set as the z-axis.

And, the y-axis refers to the axis located in the z-axis and 90° direction.

The third SAR reduction beam steering mode 230 is such that the beam radiation direction directed from the "ㅏ"-shaped transparent antenna module is oriented on the yz axis with respect to the z axis and the same as on the z axis, so that the pupils and temples of the human body It serves to form an antenna beam in the opposite direction of the human body contact based on the ground contacted with.

This sets the horizontal upper edge of the edge of the spectacle lens connected to the spectacle frame as the x-axis, the vertical lateral edge of the spectacle frame and the edge of the spectacle lens is set as the y-axis, and the position on the same line as the spectacle frame is set as the z-axis.

And, the y-axis refers to the axis located in the z-axis and 90° direction.

The glasses-mounted transparent antenna module consisting of the glasses-mounted transparent antenna unit 100 and the smart beam steering control unit 200 is, as shown in FIG. 3, a "L"-shaped transparent antenna module 1a, a "b"-shaped Any one of a transparent antenna module 1b and a "k"-shaped transparent antenna module 1c is selected and made.

The "L"-shaped transparent antenna module 1a has a ground part 100 formed on one side of the spectacle frame, and the transparent antenna part 200 is formed in the horizontal upper rim of the edge of the spectacle lens connected to the spectacle frame when viewed from a plane It serves to form a "b"-shaped transparent antenna module.

As shown in FIG. 4, this is configured on one side of the upper edge in the horizontal direction of the edge of the spectacle lens that does not interfere with the viewing angle of the spectacle lens.

The "a"-shaped transparent antenna module 1b has a ground part 100 formed on one side of the spectacle frame, and the transparent antenna part 200 is formed at the vertical side rim of the edge of the spectacle lens connected to the spectacle frame when viewed from the side It plays a role of forming a transparent antenna module in the shape of "A".

As shown in FIG. 5, it is configured on one side of the longitudinal side edge of the spectacle lens edge that does not interfere with the viewing angle of the spectacle lens.

The "ㅏ"-shaped transparent antenna module 1c is formed on one side of the top of the spectacle frame where the ground part 100 and the transparent antenna part 200 are connected to the spectacle lens to form a "ㅏ"-shaped transparent antenna when viewed from the side. It plays a role of letting go.

This is configured on one side of the upper end of the spectacle frame connected to the spectacle lens as shown in FIG. 6.

Hereinafter, a detailed operation process of the SAR reduction formation method through the glasses-attached transparent antenna module according to the present invention will be described.

[No. 1 SAR Reduced type Beam steering mode 210 Through "a" Shaped SAR of transparent antenna module Reduction formation method ]

First, as shown in FIG. 9, a ground portion 100 is formed on one side of the eyeglass frame, and the transparent antenna portion 200 is formed on the vertical side edge of the edge of the eyeglass lens connected to the eyeglass frame, An antenna module is formed (S100).

Next, the horizontal upper edge of the spectacle lens edge connected to the spectacle frame is set as the x-axis, the vertical lateral edge of the spectacle lens edge connected to the spectacle frame is set as the y-axis, and the position on the same line with the spectacle frame is set as the z-axis. Make it (S110).

Finally, the beam radiation direction directed from the "a"-shaped transparent antenna module through the first SAR reduction beam steering mode 220 is oriented on the xy axis in the same way as on the x-axis. An antenna beam is formed in a direction opposite to the human body contact based on the ground in contact with the pupil and the temple (S120).

As a result, an SAR (Specific Absorption Rate) reduction type antenna beam is formed.

[Second SAR Reduced type Beam steering mode 220 "L" through Shaped SAR of transparent antenna module Reduction formation method ]

First, as shown in FIG. 10, the ground portion 100 is formed on one side of the eyeglass frame, and the transparent antenna portion 200 is formed on the upper edge in the horizontal direction of the edge of the eyeglass lens connected to the eyeglass frame, and when viewed from a plane, "B"-shaped transparent antenna module is formed (S200).

Next, the horizontal upper edge of the spectacle lens edge connected to the spectacle frame is set as the x-axis, the vertical lateral edge of the spectacle lens edge connected to the spectacle frame is set as the y-axis, and the position on the same line with the spectacle frame is set as the z-axis. Make it (S210).

Lastly, through the second SAR reduction beam steering mode, the beam radiation direction directed from the "L"-shaped transparent antenna module is directed from the yz axis to the y axis as the reference to the y axis, so that the eyes and temples of the human body An antenna beam is formed in a direction opposite to the human body contact based on the ground in contact with (S220).

As a result, an SAR (Specific Absorption Rate) reduction type antenna beam is formed.

[Third SAR Reduced type Beam steering mode 230 Through "ㅏ" Shaped SAR of transparent antenna module Reduction formation method ]

First, as shown in FIG. 11, the ground part 100 and the transparent antenna part 200 are formed on one side of the upper end of the spectacle frame connected to the spectacle lens to form a "ㅏ"-shaped transparent antenna (S300).

Next, the horizontal upper edge of the spectacle lens edge connected to the spectacle frame is set as the x-axis, the vertical lateral edge of the spectacle lens edge connected to the spectacle frame is set as the y-axis, and the position on the same line with the spectacle frame is set as the z-axis. Make it (S310).

Finally, through the 3rd SAR reduction beam steering mode, the beam radiation direction directed from the "ㅏ"-shaped transparent antenna module is directed from the yz-axis to the z-axis as the reference to the z-axis, so that the eyes and temples of the human body An antenna beam is formed in a direction opposite to the human body contact based on the ground in contact with (S320).

As a result, an SAR (Specific Absorption Rate) reduction type antenna beam is formed.

As shown in FIG. 7, the beam pattern of the antenna designed in a design method that reduces the effect of SAR in consideration of the beam radiation of the antenna can be confirmed.

Accordingly, it is possible to reduce the amount of the beam radiated to the human body and increase the communication efficiency of the antenna.

1: glasses-mounted transparent antenna module 100: ground
200: transparent antenna unit 210: first SAR reduction beam steering mode
220: 2nd SAR reduction beam steering mode 230: 3rd SAR reduction beam steering mode

Claims (5)

delete delete delete delete A step (S300) of forming a "p"-shaped transparent antenna by forming the ground part 100 and the transparent antenna part 200 on one side of the upper end of the spectacle frame connected to the spectacle lens,
Third, the horizontal upper edge of the spectacle lens edge connected to the spectacle frame is set as the x-axis, the vertical lateral edge of the spectacle lens edge connected to the spectacle frame is set as the y-axis, and the position on the same line as the spectacle frame is set as the z-axis. xyz axis setting step (S310),
Through the 3rd SAR-reduced beam steering mode, the beam radiation direction directed from the "ㅏ"-shaped transparent antenna module is directed from the yz-axis to the z-axis and the z-axis to be in contact with the eyes and temples of the human body. SAR reduction formation method through the glasses-attached transparent antenna module, characterized in that consisting of a SAR reduction type antenna beam forming step (S320) of forming an antenna beam in a direction opposite to the human body contact with respect to the ground.

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