KR100930618B1 - Internal chip antenna structure having double parallel plate - Google Patents

Abstract

PURPOSE: An embedded chip antenna structure of a dual parallel plate is provided to select a frequency band without the change of a radiator pattern using a lumped element. CONSTITUTION: A chip antenna(100) includes a dielectric block(110), a first antenna radiation pattern electrode(120a), a second antenna radiation pattern electrode(120b). The dielectric block has a rectangular parallelepiped shape. The first and second antenna radiation pattern electrodes are formed in both sides of the dielectric block. The first and second land pads are formed on the substrate of the wireless communication device to correspond to the first and second antenna radiation pattern electrodes. The first and second antenna radiation pattern electrodes are vertically connected to the first and second land pads. The embedded chip antenna is operated by an electromagnetic field between the first and second antenna radiation pattern electrodes.

Description

Internal chip antenna structure having double parallel plate}

The present invention relates to an internal chip antenna structure in the form of a double parallel plate, and more particularly, to form an antenna radiation pattern having a simple shape on two opposite sides of a dielectric block of a chip antenna embedded in a wireless communication device, and The present invention relates to a built-in chip antenna structure in which a chip antenna is mounted on a land pad on a PCB board without a land pattern.

The biggest advantage of a chip antenna embedded in a wireless communication device is that it is a surface-mounted technic (SMT) -capable component and its size is very small compared to a general antenna.

The built-in chip antenna structure can be divided into two types for realizing two purposes. The first is to minimize the size of the built-in chip antenna mounted on the wireless device, the second is to consider the performance of the antenna, such as antenna gain improvement or antenna bandwidth (bandwidth).

In order to achieve such miniaturization and performance, conventional chip antennas have more complicated structures and shapes.

In the early chip antennas, in order to emphasize the advantages of miniaturization, the antennas are designed in a spiral type or a meander type in which the physical size of the antenna can be reduced.

Helical structure is the most basic form of small antenna design, and the long conductor is spirally wound up to have a certain pattern to form a structure with constant frequency characteristics. It can be implemented to contribute to the miniaturization of the antenna size.

The zigzag antenna structure also reduces the physical length of the antenna in a manner similar to the spiral antenna structure. FIG. 1 shows a chip antenna of the related art 1 which is a general embodiment having a zigzag antenna structure, and is shown in FIG. In the related art 1, the zigzag side electrodes 11 and the upper and lower electrodes 12 are formed on the dielectric block 13, and one end thereof is connected to the ground electrode 10. In general, the antenna is designed in a state without the ground interference in all directions around the antenna. The antenna of the spiral structure or the zigzag structure has a change in antenna performance as the ground approaches the antenna. There is a problem in that the gain is lowered.

As a structure for improving the performance of the antenna, there is a Planar Inverted F-Type Antenna (PIFA), Figure 2 shows a prior art 2 as an embodiment of the PIFA antenna, the chip antenna 20 of the prior art 2 is opposed to each other The radiation electrode 27, the ground electrode 23, and the power feeding pattern 25 are formed on the dielectric block 22 having the first main surface 22a and the second main surface 22b, respectively. Such a FIPA antenna is designed in a condition close to ground from the design time, so that a good antenna gain can be obtained even in a close ground condition. However, the FIPA antenna has a narrow bandwidth compared to a spiral or zigzag structure.

In addition, land pads exist for mounting surface mounted device (SMD) components on a PCB substrate. In the case of a rectangular chip antenna, a chip antenna is generally used to satisfy the characteristics of the antenna. There is a land pad for mounting and comprises a side pattern connected to the land pad and an upper side pattern extending in connection with the side pattern to include a radiator pattern constituting an antenna on at least three of six surfaces of the rectangular parallelepiped. It is inconvenient to form a land pad having a complex pattern on a PCB substrate so as to correspond to the antenna pattern.

As described above, in the case of an embedded chip antenna according to the prior art, a complex pattern structure is formed in a rectangular parallelepiped space of a small chip antenna in order to achieve the purpose of the antenna. It is designed by forming a radiation pattern on almost all six sides of a rectangular parallelepiped including a pattern. In the case of LTCC (Low Temperature Co-fired Ceramics) chip antennas, the internal space can be used to form a thrugth hole or via hole that connects the radiation pattern to the inside of the chip antenna even if the outer surface of the cube is not used. There is a problem in that the complexity of the design is increased, such as adding a process.

Furthermore, since antennas are generally manufactured on the assumption that ground is assumed, their results will change as the assumptions change. In fact, in the case of antennas embedded in many wireless communication devices, the surrounding ground conditions are often changed by various conditions of the wireless communication system. Therefore, in the case of the built-in chip antenna, even if the same antenna is changed according to the change of ground conditions, The characteristics will be different.

In other words, the operating frequency changes and the structural impedance changes. In this case, the basic antennas may consider moving to a new position having different lengths of radiation patterns or other conditions to adjust the operating frequency. In addition, by changing the radiation pattern structure of the antenna in order to change the structural impedance, the electrical characteristics are changed to satisfy the desired characteristics.

However, such a design change does not necessarily satisfy the desired performance, and it is cumbersome to redesign the antenna with a completely different shape.

As described above, in order to obtain desired electrical characteristics by applying to various wireless communication systems, there is a problem of reflecting different antenna designs for various wireless communication systems.

The present invention is to provide a structure of a built-in chip antenna that minimizes the size of the built-in chip antenna and at the same time implements the same performance as the existing antenna.

In the case of the built-in antenna, the size of the antenna radiator pattern is limited because it is located inside the device, and to solve the problem that the production process is complicated and the production cost is increased by forming a complex antenna radiator according to the characteristics of the frequency band. It is an object to provide a chip antenna of a simple structure.

In addition, in the case where the embedded chip antenna is mounted on the board of the wireless communication device, land pads for connecting the antenna and the PCB board are complicated to be formed in accordance with the antenna pattern.

In order to achieve the above technical problem, the present invention, in the structure of the built-in chip antenna, each antenna radiation pattern electrode is formed on two opposite sides of the dielectric block formed of a rectangular parallelepiped including a dielectric is formed, each wireless communication Land pads are formed on the substrate of the device to correspond to the respective antenna radiation pattern electrodes, and each antenna radiation pattern electrode is vertically connected to each of the land pads. The antenna is operated by an electromagnetic field generated between the antenna radiation pattern electrode formed on the two sides facing each other is a built-in chip antenna structure of the double parallel plate shape.

Preferably, when the dielectric block is mounted on a substrate of a wireless communication device, a surface on which the antenna radiation pattern electrode is formed may be vertically connected to a land pad on the substrate of the wireless communication device.

Here, the antenna radiation pattern electrode may be formed in a symmetrical form on two opposite sides of the dielectric block.

Further, the dielectric block may be mounted by forming a solder fillet in a solder paste on a portion where the antenna radiation pattern electrode and the land pad on the substrate of the wireless communication device are in contact with each other.

Preferably, one side of the first land pad connected to any one antenna radiation pattern electrode among two antenna radiation pattern electrodes formed in a symmetrical shape on the two sides may be connected to a signal line of the wireless communication device. The other side of the first land pad may be connected to the ground through the first electrode line.

In addition, one side of the second land pad connected to the other antenna radiation pattern electrode among the two antenna radiation pattern electrodes formed in a symmetrical shape on the two sides may be connected to the ground through the second electrode line.

In addition, the second electrode line may include a Lumped Element for selecting a frequency band.

According to the present invention as described above, the size of the built-in chip antenna can be further miniaturized, and the structure of the antenna radiator is simple, so that the production is easy and the production process and the unit cost are reduced.

In addition, since the chip antenna of the dual parallel plate structure is not limited in the direction of orientation when mounted inside the wireless communication device, there is no limitation of the mounting position, thereby facilitating the design of the wireless communication device.

Furthermore, it is not necessary to form a land pad pattern corresponding to the antenna radiator pattern for mounting the chip antenna on the board of the wireless communication device. The antenna is applied in all frequency bands of 1 GHz or more without changing the radiator pattern through the lumped constant element. It can work.

In order to explain the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, the following describes exemplary embodiments of the present invention and looks at it with reference.

When the chip antenna is mounted on a substrate of a wireless communication device, the antenna radiation pattern electrodes are formed only on two opposite sides perpendicular to the substrate among the six surfaces of the rectangular parallelepiped block, so that the shape of the chip antenna is left and right and It proposes a structure of a built-in chip antenna of a double parallel plate in which the top and bottom are symmetrical and maintain the same shape even when mounted in any direction.

3 is a perspective view and an exploded view of one embodiment of a built-in chip antenna in the form of a double parallel plate according to the present invention.

As shown in (a) of FIG. 3, the chip antenna 100 according to the present invention forms the antenna radiation pattern electrode 120 on the side of the dielectric block 110 formed of a rectangular parallelepiped. As shown in b), the antenna radiation pattern electrode is formed of the first antenna radiation pattern electrode 120a and the second antenna radiation pattern electrode 120b on each of two opposite sides of the dielectric block 110.

According to the present invention, an electromagnetic field generated between two opposite radiation pattern electrodes 120a and 120b is formed by forming antenna radiation pattern electrodes 120a and 120b on two opposite sides on the dielectric block 110, respectively. The chip antenna 100 is operated.

Here, the size of the chip antenna 100 including the dielectric block on which the radiation pattern electrode is formed is a rectangular parallelepiped such as 2.0 × 1.2 × 1.2mm ³ or 3.0 × 1.2 × 1.2mm ³ , which can further reduce the size of the chip antenna. Can be.

4 illustrates a form in which a chip antenna according to the present invention is bonded to a land pad.

In mounting the dielectric block 110 having the antenna radiation pattern electrode 120 according to the present invention on a substrate of a wireless communication device, the side surfaces on which the antenna radiation pattern electrode 120 is formed are land pads 210a and 210b on the substrate. It is mounted on the point 170 where the dielectric block 110 on the substrate to be perpendicular to the ().

As shown in FIG. 4, in the present invention, the structure of the chip antenna 100 does not need to form a separate pattern for connecting with the land pad of the substrate on the bottom surface of the dielectric block 110. 210a and 210b may also be formed in a simple structure without forming a complicated pattern.

In addition, a double parallel plate structure in which the radiation pattern electrodes 120a and 120b are formed on two opposite surfaces of the dielectric block 110, respectively, has the same shape even when the antenna is rotated 180 degrees with respect to the horizontal axis or the vertical axis. It is convenient to maintain.

5 illustrates a state in which a chip antenna according to the present invention is mounted on a substrate of a wireless communication device.

As shown in FIG. 5, the PCB layout 200 for mounting the chip antenna 100 according to the present invention on a wireless communication device may be formed in a very simple structure, which is a plan view of the PCB layout of FIG. 6. Referring to FIG. 1, the first land pad 210a and the second land for connecting two radiation pattern electrodes 120a and 120b formed on two opposing side surfaces of the dielectric block 110 of the chip antenna 100, respectively. A pad 210b is formed, where one side of the first land pad 210a is connected to the signal line 220 of the wireless communication device and the other side of the first land line 210a extends from the first land pad 210a. Through ground 270 on the PCB substrate.

In addition, the second electrode line 260b extending from the second land pad 210b includes a Lumped Element 250 for selecting a frequency band and is connected to the ground 270 on the PCB substrate.

As described above, the first radiation pattern electrode 210a of the two radiation pattern electrodes 210a and 201b formed to face the radiator block 110 of the chip antenna 100 is connected to the signal line 220 and the ground 270. The other second radiation pattern electrode 210b is connected only to the ground 270 to operate the antenna by an electromagnetic field formed between the first radiation pattern electrode 210a and the second radiation pattern electrode 210b. It becomes possible.

Furthermore, the chip antenna 100 according to the present invention may fix the antenna dielectric block 110 and simultaneously connect the antenna radiation pattern electrodes 120a and 120b to the land pads 210a and 210b on the substrate. Solder Fillet), FIG. 7 illustrates an embodiment of SMT using solder fillets.

When the radiation pattern electrodes 120a and 120b of the chip antenna 100 are brought into close contact with the PCB land pads 210a and 210b of the wireless communication device and a constant temperature is applied, the Ag pattern and the land of the PCB, which are radiation pattern electrodes of the antenna having good thermal conductivity, are applied. A solder fillet may be formed on a copper pad plated with Au, which is a pad, so that the chip antenna 100 may be SMT. When a predetermined temperature is applied to the PCB, the solder paste may have a good thermal conductivity. A solder fillet is formed by riding the Ag patterns of the side radiation pattern electrodes 120a and 120b.

As described above, the SMT of the chip antenna 100 according to the present invention does not require a separate land pattern for mounting the chip antenna 100 on the PCB substrate.

8 to 10 further illustrate various embodiments of a chip antenna according to the present invention.

In the embodiment of FIG. 8, in forming the radiation pattern electrodes 121 on opposite sides of the dielectric block 110, the centers of the radiation pattern electrodes 121a and 121b have a rectangular ring shape. In the ninth embodiment, the inside of each of the radiation pattern electrodes 122a and 122b is zigzag-open, and in the embodiment of FIG. 10, each of the radiation pattern electrodes 123a and 123b is formed in a square hoof shape. have.

Furthermore, radiation patterns may be formed on two opposite sides of the dielectric block 110 in the shape of various modified shapes as well as the pattern shapes shown in the above embodiments, and in the above embodiment, two radiation patterns may be formed. The electrodes are formed in a symmetrical form with each other, but may be variously formed in asymmetrical forms with each other.

11 shows an embodiment of various PCB layouts in which a chip antenna according to the present invention is mounted.

As shown in (a) to (c) of FIG. 11, the land pad 210a connecting one radiation pattern electrode is connected to various types of signal lines 220a, 220b, and 220c on one side thereof. As shown in (b), the other side may be connected to the ground 270b through the extended electrode line 260a.

In the land pad 210b connecting the other radiation pattern electrode, the electrode line 260b extending from the land pad 210b includes the lumped water purification element 250 and may be simultaneously connected to the ground 270 of the PCB substrate.

The PCB layout shown in FIG. 11 is an embodiment, and is not limited thereto, and may be modified in various forms to form an electromagnetic field between two radiation pattern electrodes facing each other according to the present invention.

The chip antenna structure according to the present invention can operate at any frequency of 1GHz or more at the same time, which can greatly reduce the size of the chip antenna, GPS, PCS, DCS, WCMA, DMB, Bluetooth, W-LAN, WIFI, Wibro, etc. It can be applied to various single band wireless communication devices. In addition, the chip antenna structure according to the present invention has an antenna gain that satisfies 0dBi on average, thereby miniaturizing the size, but more effectively shows its performance.

As described above, the present invention can further reduce the size, which is an inherent advantage of the chip antenna, and at the same time, it is possible to implement performance equivalent to or higher than that of the existing antenna.

Furthermore, the antenna structure according to the present invention is very simple in its structure and shape through the optimization of the design it is possible to reduce the production cost and development cost during mass production of the product.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments described in the present invention are not intended to limit the technical idea of the present invention but to explain, and the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1 shows a perspective view of a chip antenna perspective view and a conductor pattern of the prior art 1,

Figure 2 shows a perspective view of the chip antenna of the prior art 2,

3 is a perspective view and an exploded view of one embodiment of a built-in chip antenna in the form of a double parallel plate according to the present invention,

4 illustrates a form in which a chip antenna according to the present invention is bonded to a land pad,

5 illustrates a state in which a chip antenna according to the present invention is mounted on a substrate of a wireless communication device.

6 shows a top view of a PCB layout according to the invention,

7 shows an embodiment of an SMT using a solder fillet,

8 to 10 show embodiments of various radiation patterns of the chip antenna according to the present invention,

11 shows an embodiment of various PCB layouts in which a chip antenna according to the present invention is mounted.

<Description of Major Symbols in Drawing>

100: chip antenna, 110: dielectric block,

120, 120a, 120b: antenna radiation pattern electrode,

150: solder fillet, 200: PCB layout,

210a: first land pad, 210b: second land pad,

220: signal line, 270: ground.

Claims (8)

In the structure of the built-in chip antenna, Each antenna radiation pattern electrode is formed on two opposing sides on a dielectric block formed of a rectangular parallelepiped including a dielectric, Land pads are formed on the substrate of the wireless communication device to correspond to the respective antenna radiation pattern electrodes. Each of the antenna radiation pattern electrodes is vertically connected to each of the land pads, The integrated chip antenna structure of the dual parallel plate shape, characterized in that the antenna is operated by the electromagnetic field generated between the antenna radiation pattern electrodes formed on the two sides facing each other. delete The method of claim 1, And an antenna radiation pattern electrode is formed on two opposite sides of the dielectric block to be symmetrical with each other. The method of claim 1, A dual parallel plate-type embedded chip, wherein the dielectric block is mounted by forming a solder fillet in a solder paste on a portion where the antenna radiation pattern electrode and the land pad on the substrate of the wireless communication device are in contact with each other. Antenna structure. The method of claim 3, wherein Double parallel plates, characterized in that one side of the first land pad connected to any one antenna radiation pattern electrode of the two antenna radiation pattern electrodes formed in a symmetrical shape on the two sides is connected to the signal line of the wireless communication device Built-in chip antenna structure. The method of claim 5, wherein The other side of the first land pad, the built-in chip antenna structure of the double parallel plate shape, characterized in that connected to the ground through the first electrode line. The method of claim 5, wherein One side of the second land pad connected to the other antenna radiation pattern electrode of the two antenna radiation pattern electrodes formed in a symmetrical shape on the two sides, it is connected to the ground through a second electrode line Built-in chip antenna structure in the form of a parallel plate. The method of claim 7, wherein The second electrode line has a built-in chip antenna structure of a double parallel plate type, characterized in that it comprises a Lumped Element (Lumped Element) for frequency band selection.

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