KR100969274B1 - non-square patch antenna - Google Patents

Abstract

Non-square patch antennas are disclosed. Non-square patch antenna according to the present invention, the width and length ratio of the dielectric block formed in a non-square to be installed on the inner side of the wireless communication device; A conductive pattern coated differently in a ratio of width and length to an upper end of the dielectric block; And an input / output terminal electrically connected to a conductive pattern of an upper end portion of the dielectric block and electrically separated from a ground surface of the lower end portion of the dielectric block through the dielectric block. It is characterized by having a circular polarization characteristic or a linear polarization characteristic by adjusting.

Patch Antenna, Non-Square Patch Antenna, Integrated Antenna

Description

Non-square patch antenna

The present invention relates to an antenna and an antenna module for receiving a satellite signal or a gap filler signal on the ground. More specifically, the present invention relates to a global positioning system (GPS), a digital multimedia broadcasting (DMB), and a digital audio broadcasting (DAB). The present invention relates to a non-square patch antenna of a dielectric block for receiving a satellite signal or a gap filler signal, and an integrated antenna module including the same.

In recent years, the use of wireless communication is rapidly increasing, and in order to meet the popularization of wireless communication devices, a slim antenna that can be mounted inside a transceiver according to the trend of focusing on design and cost reduction and mass production while maintaining the performance of the antenna Demand is rising.

In general, a microstrip patch antenna is used in a vehicle receiver for using mobile multimedia information, a broadcasting service, or a current location and an electronic map service. The reason is that in order to minimize the influence of the ionosphere interference and the multipath signal (noise) reflected from the ground, the satellite transmits a right hand circular polarization and receives the GPS satellite signal. Circular polarization antenna is used because patch antenna is cheap and good reception rate among various kinds of circular polarization antenna. The patch antenna is a kind of antenna that is light in weight and has a flat structure that takes up little space but can have the largest gain and directivity in a given space. It is used as a communication relay antenna of various mobile communication devices and portable devices. .

1 is an exploded view showing the structure of a patch antenna according to the prior art, which is shown in the top and bottom surfaces.

As shown in FIG. 1, the conventional patch pin type square patch antenna includes an antenna module 12 and a printed circuit board (PCB) 14 separated therefrom. The antenna module 12 is coated with a conductive material on both end surfaces of the dielectric block 11, the feeding pin 13 is located on the top surface. In addition, one or more low noise amplifiers 15 are formed in the PCB 14, and the PCB 14 is attached to the bottom surface of the antenna module 12. The conductive surface of the top surface is coated with a conductive material in the same ratio of width and length to implement circular polarization characteristics. In addition, the feeding pin 13 is electrically connected to the conductive surface of the top surface to penetrate through the dielectric block, but is formed to be electrically separated from the ground surface made of the conductive material of the bottom surface.

However, the problem of the patch antenna used in the conventional navigation and the like is that a 'ground plane', for example, basically a flat conductive surface is required, and in order to facilitate the reception of satellite signals, the PCB must have a ground plane with a sky cross section. Is that. In addition, the size of the smallest patch antenna currently used is 18 × 18mm, it is difficult to mount in the user equipment due to the limitation of the width of the receiver and the antenna height problem. Thus, as can be seen in Figure 2 showing a navigation with a square patch antenna as described above, the antenna mechanism 18, which can be unfolded and folded from the body, is located behind the top of the navigation 17, and within Since there is no choice but to configure the patch antenna to be positioned, there is a problem that the antenna mechanism protrudes laterally as much as the width of the antenna when used.

In recent years, as the trend toward slimmer and smaller portable devices has been combined with the functions of products, for example, a car navigation company needs to develop a navigation device that can be mounted on a vehicle and is portable with a built-in battery. However, as described above, the conventional patch antenna does not become slim and increases the size of navigation and the like, and even when mounted in a vehicle using a small patch antenna of 13 × 13 mm or less, the antenna characteristics are not good, so reception in a shaded area is not possible. There is also the problem of instability. In addition, the square patch antenna has a characteristic of selectively receiving left hand circular polarization and right hand circular polarization when receiving a satellite signal with a circular polarization antenna. You need to redesign based on whether it is polarized or port polarized. In the case of designing a dual band antenna, the reception rate may be reduced due to the mutual interference effect according to the design of the left polarized wave receiving antenna and the star polarized wave receiving antenna.

On the other hand, according to the miniaturization trend, there have been attempts to use a smaller patch antenna or linear polarization antenna of 13 × 13 mm or less, but the smaller the antenna, the lower the performance and reception sensitivity of the antenna, for example, a signal of -130 dbm is used. In the case of existing GPS engines, signal processing is not possible. Therefore, in the current market, there is a demand for the development of an antenna or an antenna module that can be built to satisfy the miniaturization and portability while maintaining or exceeding a conventional antenna.

The present invention has been made to solve the structural problems and design problems of the receiver such as the navigation according to the use of the conventional square patch antenna described above, the patch antenna positioned on the non-square dielectric block and the non-square dielectric block By adjusting the conduction pattern of the non-square patch antenna of the dielectric block having circular polarization characteristics or improved linearly polarizing characteristics, and extending the conductive pattern of the upper surface to the side of the non-square dielectric block has circular polarization characteristics or Provides a non-square patch antenna of a dielectric block having a linear polarization characteristics, and implements a conductive pattern formed with one or more grooves in the upper end of the dielectric block to facilitate mounting of a patch antenna having a circular polarization characteristics inside the user equipment Providing antenna module And a purpose.

In addition, by implementing the integrated antenna module to attach the patch antenna and the low noise amplifier to a single PCB, and the integrated antenna module to attach the patch antenna and the GPS engine module to a single PCB, the reception performance of the antenna is as good as the conventional antenna The object of the present invention is to develop an antenna or an antenna module that can be maintained or more and can be built to satisfy miniaturization and portability.

A first embodiment of a non-square patch antenna according to the present invention for achieving the above object is a dielectric block formed in a non-square in a different ratio of width and length so that it can be installed on the inner side of the wireless communication device; A conductive pattern coated differently in width and length in the upper end of the dielectric block; And an input / output terminal electrically connected to a conductive pattern of an upper end portion of the dielectric block and electrically separated from a ground surface of the lower end portion of the dielectric block through the dielectric block. It characterized in that the linear polarization characteristics are adjusted by adjusting.

Here, the conductive pattern is applied extending from both the upper end of the dielectric block to both sides of the longer side, it is preferable to have a circular polarization characteristic or a linear polarization characteristic by adjusting the size of the conductive pattern.

In addition, the dielectric block is formed with a groove penetrating from the upper end to the lower end, and the input and output terminal is preferably formed by filling the inside of the groove with a conductive material containing silver (Ag).

Preferably, the conductive pattern has at least one groove formed by removing the conductive pattern from both sides of the shorter side at the upper end of the dielectric block, and has a circular polarization characteristic or a linear polarization characteristic by the conductive pattern. Adjusted.

A second embodiment of a non-square patch antenna according to the present invention comprises a dielectric block formed of a non-square in a different ratio of width and length so as to be installed on the inner side of the wireless communication device; A conductive pattern coated differently in a ratio of width and length to an upper end of the dielectric block; And an input / output terminal electrically connected to a conductive pattern of an upper end portion of the dielectric block and electrically separated from a ground surface of the lower end portion of the dielectric block through the dielectric block. It is characterized by having a circular polarization characteristic or a linear polarization characteristic by adjusting.

Here, in the non-square patch antenna, the conductive pattern may be formed with at least one groove in which the conductive pattern is removed from both sides of the shorter side at the upper end of the dielectric block, the circular polarization by the conductive pattern Will have characteristics. In this case, the dielectric block uses a high dielectric constant of 37 or more, and if the short side of the non-square dielectric block is sufficiently large by 13 mm or more, the dielectric block may have no groove without the short conductive pattern removed from the conductive pattern located on the non-square dielectric block. The conductive pattern has circular polarization characteristics.

By adjusting the conductive patterns of the non-square dielectric block and the patch antenna located on the non-square dielectric block, the non-square patch antenna of the dielectric block having circular polarization characteristics or improved linear polarization characteristics, and the non-square dielectric The conductive pattern on the top surface is extended to the side of the block to have circular polarization characteristics or linear polarization characteristics.

An embodiment of a non-square patch antenna of a dielectric block according to the present invention will be described in detail with reference to FIGS. 3A to 5.

3A to 3C are diagrams illustrating embodiments of a non-square patch antenna of a dielectric block having linear polarization characteristics according to the present invention.

Figure 3a is a view showing the top, side and bottom surfaces of the first embodiment of the non-square patch antenna of the dielectric block according to the present invention, respectively.

As shown, the patch antenna according to the first embodiment of the present invention is a feeding pin type patch antenna, which is composed of a dielectric block 21 and a conductive pattern 22. Here, the dielectric block (hereinafter, also referred to as 'dielectric block') 21 is formed in a non-square, and the conductive pattern 22 is horizontally and horizontally corresponding to the shape of the dielectric block 21 at the upper end of the dielectric block 21. The vertical ratio is applied differently. At this time, the ratio of the width and length of the conductive pattern 22 is less than 13mm, the width of the patch antenna to be mounted inside the user equipment such as navigation, the width is in the non-square form of 18 ~ 35mm or 35mm or more. If the width of the set permits, such as 7-inch navigation, it is preferable to implement it, and the antenna characteristics can be improved by increasing the width (shortening) of the dielectric block to 13-18 mm.

The feeding pin 23 is electrically connected to the conductive surface of the upper end in the conductive surface 22 of the upper end of the patch antenna and penetrates through the dielectric block 21 and electrically to the conductive surface 24 of the lower end. It is formed to be separated.

Figure 3b is a view showing the top, side and bottom surfaces of the second embodiment of the non-square patch antenna of the dielectric block according to the present invention.

As shown, the patch antenna according to the second embodiment of the present invention is a surface mount technology (SMT) type antenna, and the front surface of the top surface of the dielectric block 31 of the patch antenna. Although the drawing 32 is electrically insulated from the ground surface of the bottom surface, the inside of the hole 34 includes silver (Ag), unlike the way in which the feeding pin 23 of the first embodiment protrudes from the bottom of the dielectric block. As it is filled with a conductive material, it is electrically connected to the input / output terminal 33 and the conductive surface 32 of the upper end of the dielectric block and penetrates the dielectric block 31 and is open to the ground surface 35 made of the conductive material at the lower end. . The shape of the dielectric block 31 and the conductive pattern 32 at the upper end is the same as that of FIG. 3A.

3C is a view showing third embodiments of a non-square patch antenna of a dielectric block according to the present invention.

As shown, the patch antenna according to the third embodiment of the present invention is another patch antenna of the SMT type, wherein the conductive surface 42 of the upper surface of the dielectric block 41 is made of a ground material (conductive material of the lower surface). 43 and a conductive input / output terminal 44 electrically separated from the ground conductive surface 43 at the lower end thereof, and a conductive matching pattern 45 on one side thereof to match the input / output terminal. This is done by applying SMT to form. Also in this case, the shape of the dielectric block 41 and the conductive pattern 42 at the upper end is the same as that of FIG. 3A.

The patch antenna may implement various types of patch antennas using various materials. However, the patch antenna according to the present invention uses a ceramic dielectric having a high dielectric constant of 6 to 60, thereby improving performance (gain x bandwidth and volume). However, since it can be small and have a low profile, it contributes to the miniaturization of a communication device and has an advantage that the risk of damage to an external shock to the device is small due to the built-in type. In addition, the ceramic antenna according to the present invention can exhibit a sufficient performance in the frequency range of several hundred MHz to several GHz used by most systems, such as wireless communication or mobile phones, the use area will be broadened in the future.

Square patch antenna according to the prior art, when developed as a patch antenna having the characteristics of starboard polarization, there is a problem that can receive only satellite signals of starboard polarization due to the reception characteristics and satellite signals sent to the left side polarization cannot be received. . On the other hand, since the non-square patch antenna according to the present invention has a characteristic of linear polarization, it is possible to receive a wide range of signals regardless of the polarization direction of the satellite signal, and GPS, such as SIRstar 3, which has improved signal processing characteristics. Receive performance can be complemented by the engine. In addition, due to the characteristics of the linearly polarized light of the non-square patch antenna according to the present invention, as in the case of the conventional square patch antenna, it is possible to solve the problem that the reception rate is lowered due to the mutual interference caused by the circular polarization, the design of the dual band Is easy.

4A to 4C are diagrams illustrating still other embodiments of a non-square patch antenna of a dielectric block according to the present invention.

Figure 4a is a view showing the top, side and bottom surfaces of a fourth embodiment of the non-square patch antenna of the dielectric block according to the present invention.

The patch antenna according to the present invention is a non-square patch antenna of a feeding pin type, and is composed of a dielectric block 51 and a conductive pattern 52. Here, the dielectric block 51 is formed in a non-square, the ratio of the width and length of the conductive pattern 52 applied to the upper end of the dielectric block 51 is different, the conductive pattern 52 to both sides of the longer side The feeding pin 53 is positioned in the conductive surface 52 of the upper end of the patch antenna, and is electrically connected to the conductive surface of the upper end of the patch antenna, penetrating the upper and lower end surfaces of the dielectric block 51, and the conductive material of the lower end. It is electrically separated from the ground surface 54 which was formed. By forming a conductive pattern on the side of the dielectric block, it is possible to implement the circular polarization characteristics electrically, and by adjusting the ratio of the horizontal and vertical length of the conductive pattern extending to the side can exhibit a linear polarization characteristic improved electrical properties.

Figure 4b is a view showing the top, side and bottom surfaces of the fifth embodiment of the non-square patch antenna of the dielectric block according to the present invention.

The patch antenna according to the present invention is an SMT type non-square patch antenna, in which the conductive pattern 62 is extended to both sides of the long side of the dielectric block 61 in the same manner as the patch antenna of the fourth embodiment. Structure. Instead of the feeding pin 53 of the fourth embodiment, the input / output terminal 63 and the inside of the hole 64 are coated with silver (Ag) to electrically connect the input / output terminal 63 and the conductive surface 62 of the upper end, and It is a patch antenna that allows the SMT to be applied by implementing the conductive pattern 64 made of silver to open through the dielectric block to the ground surface 65 made of the conductive material at the lower end thereof.

4C illustrates a sixth embodiment of a non-square patch antenna of a dielectric block according to the present invention.

The patch antenna according to the present invention is another non-square patch antenna of the SMT type, and the conductive pattern 72 is extended to both sides of the long side of the dielectric block 71 in the same manner as the patch antenna of the fourth embodiment. It is an extended structure. The conductive surface 72 of the top surface of the dielectric block 71 of the patch antenna is electrically separated from the ground surface 73 made of a conductive material at the bottom, and is electrically separated from the ground conductive surface 73 at the bottom. SMT is applied to form a conductive input and output terminal 74, and to form a conductive pattern 75 on either side of the opposite side of the conductive pattern 72 is extended to match the input and output terminals.

The non-square patch antennas of the dielectric blocks according to the fourth to sixth embodiments of the present invention form circular polarization characteristics by forming a conductive pattern on the sides of the dielectric block and the ceramic block having different widths and lengths, or the conductive patterns. The non-square patch antenna of the dielectric block, which improves the characteristics of the linearly polarized wave according to the size adjustment, is also a miniaturized antenna than the conventional square patch antenna, which can be mounted inside the user equipment and improves the reception performance. In addition, unlike the square patch antenna, it is possible to design a dual band. Particularly, when the circular polarization characteristic is used, the reception characteristics of the conventional patch antenna can be reduced while maintaining the reception characteristics of the conventional patch antenna, thereby enabling the transmission and reception of two or more channels at one frequency and taking advantage of the circular polarization with low polarization loss. .

5 shows a seventh embodiment of a non-square patch antenna of a dielectric block according to the present invention.

The patch antenna according to the present invention implements a conductive pattern 78 having a groove formed by removing one or more conductive patterns on both sides of the shorter side of the dielectric block 76 having different ratios of width and length, and feeding pins. 77 is located in the conductive surface 78 of the upper end of the patch antenna, and electrically connected to the conductive surface of the upper end of the patch antenna, penetrating the upper and lower surfaces of the dielectric block 76, and the ground conducting surface 79 of the lower end. ) Is electrically isolated. The patch antenna has two antenna characteristics of a linearly polarized wave type, each of which is separated by high frequency and low frequency at 13 mm on one side. As the grooves are added while removing the shorter side of the conductive pattern, the width of the conductive pattern narrows to less than 13 mm, shifting the characteristics of other linearly polarized antennas in the 1.8 Ghz band to approximate another low frequency linearly polarized characteristic. As a result, each linearly polarized antenna characteristic has a circular polarization characteristic with a frequency, magnitude, and phase angle of 90 degrees. In particular, in the case of circular polarization characteristics, polarization is possible because the conductive pattern is realized on a long-axis dielectric ceramic block having high quality (Q * f: quality characteristics of materials) while maintaining the reception characteristics of the conventional patch antenna. Not only can it take advantage of the circularly polarized wave with a small loss, but also has better characteristics against noise than a square antenna.

The patch antenna in which the groove is formed in the conductive pattern is not limited to the above-described specific embodiments, and is applied to all of the second to sixth embodiments according to the present invention, thereby providing various types of non-square patches of the feeding pin type or the SMT type. Circular polarization characteristics can be realized with an antenna. In particular, non-square patch antennas, such as 13 × 18mm or 13 × 20mm, can realize circular polarization characteristics by extending the conductive pattern to the side of the dielectric block, but the length of one side is considerably longer like a 13 × 25mm patch antenna. In this case, it is preferable to implement circular polarization characteristics by forming a groove in the conductive pattern of the upper end while extending the conductive pattern on the side.

Since the patch antenna according to the first to sixth embodiments implements a linear shape having a length of 13 mm and a width of 18 to 35 mm or 35 mm or more due to the width of the user equipment such as navigation, the user equipment Can be mounted inside. In addition, while reducing the size of one side, it is possible to improve Q * F by using a high dielectric constant of Er 60 or less. For example, a 13 × 18 mm patch antenna can use ceramic powder with a relative dielectric constant (Er) of 45 or more, with a Q * F of 40,000 or more, and a relative dielectric constant with a Q * F of 35,000 for a 13 x 20 mm patch antenna. By using the ceramic powder of (Er) 37, the loss caused by the raw material can be reduced, the antenna gain can be improved, and the reception characteristics are better than that of the conventional square patch antenna.

Hereinafter, embodiments of the integrated antenna module including the non-square patch antenna of the dielectric block according to the present invention will be described in detail with reference to FIGS. 6 to 14C.

6 is a view showing a first embodiment of an integrated antenna module according to the present invention.

In the integrated antenna module according to the present embodiment, SMD (Surface Mount Devices) method on the same surface of the narrow rectangular rectangular antenna (83) of the non-square patch antenna 81 and the low noise amplifier 82 of the dielectric block-hole in the PCB It is attached by means of attaching elements and soldering them on a printed board that is soldered without soldering. The transmission line 84 for transmitting satellite signals from the low noise amplifier 82 to the engine is connected. . According to the present invention, the integrated antenna module has a width of 65 × 10 × 4.7 mm and only a portion where the patch antenna 81 is positioned to have a width of 13 mm, and the width thereof is narrowed rather than longer than the square patch antenna. By implementing the patch antenna and the low noise amplifier on the same surface of the PCB, the antenna height can be reduced, thereby optimizing the design in the user equipment.

7 is a block diagram of a low noise amplifier used in the integrated antenna module according to the present invention.

The circuit of the low noise amplifier 82 firstly amplifies the satellite signals received from the non-square patch antenna 81 of the dielectric block according to the present invention, and then through the bandpass filter 8204, the second amplification 8208. It is configured to be done. Signals up to the second amplification are sent to the GPS engine via a connected cable. The low noise amplifier has a problem of narrowing bandwidth due to miniaturization according to a high dielectric constant of an antenna that can be used in the antenna module, thereby amplifying the received satellite signal to be processed by a GPS engine. There is also a method of attaching the patch antenna directly to the GPS engine, but in this case, since the satellite signal is too weak to be vulnerable to noise, the GPS may be amplified by gain of at least 24 dB through amplification and filtering by a low noise amplifier as described above. It is desirable to have a signal input to the engine.

8 is a view showing a second embodiment of an integrated antenna module according to the present invention.

In the integrated antenna module according to the present embodiment, the non-square patch antenna 81 and the low noise amplifier 82 of the dielectric block are respectively attached to different surfaces of the PCB 83 by SMD (Surface Mount Devices) method, and low noise A transmission line 84 for transmitting satellite signals from the amplifier 82 to the engine is connected. According to the configuration in which the patch antenna 81 and the low noise amplifier 82 are attached to different surfaces of the PCB 83 as described above, the noise effect of the low noise amplifier generated from the signal transmission process to the non-square patch antenna is minimized. It also has advantages.

9 is a view showing a third embodiment of the integrated antenna module according to the present invention.

In the integrated antenna module according to the present embodiment, two blocks of the PCB 83 end to which the patch antenna 81 of the dielectric block is attached and the PCB end 84 to which the low noise amplifier 82 is attached are coaxial cables. Connected to 85. In this case, both PCB stages may have a rectangular shape, but the present invention is not limited thereto. The PCB may be replaced with a flexible PCB. According to the antenna module of this configuration, the PCB stage 84 to which the low noise amplifier 82 is attached has an advantage of free 360 ° rotation. That is, when spatial constraints and bending in the receiver are required according to the use of the coaxial cable, not only an antenna module may be implemented as shown in FIGS. 10A to 10C, but the present invention is not limited thereto and may be implemented in various forms according to a designer's intention. This is possible.

11 is a view showing a fourth embodiment of the integrated antenna module according to the present invention.

The integrated antenna module according to the present embodiment includes a non-square patch antenna 81 of a dielectric block according to the present invention, and a miniaturized GPS engine that performs data associating with a satellite signal received by the patch antenna to output data. GPS engine module 91 is SMD (Surface Mount Devices) method on the same side of narrow and long rectangular PCB 92-Automatically by attaching elements on soldered printed board without melting holes and melting lead The method of mounting is attached. According to the present invention, the GPS smart antenna module has a width of 65 × 10 × 7mm and only a portion where the patch antenna 81 is positioned to have a width of 13 mm or less so that the width thereof is narrow rather than longer than the square patch antenna. Losing character. On the other hand, by replacing the DAB or DMB antenna and the GPS engine using the above method with a DAB engine or DMB engine, the integrated GPS antenna engine module can be used for DAB or DMB as well as navigation or GPS.

12 is a view showing a fifth embodiment of the integrated antenna module according to the present invention.

In the integrated antenna module according to the present embodiment, the non-square patch antenna 81 and the GPS engine module 91 of the dielectric block according to the present invention are provided with SMD (Surface Mount Devices) method on different surfaces of the PCB 92. Each is attached. Thus, according to the configuration in which the patch antenna 81 and the GPS engine module 91 are attached to different surfaces of the PCB 92, the effect of noise on the patch antenna in the low noise amplifier of the GPS engine module generated in the signal transmission process is affected. It also has advantages that can be minimized.

13 is a view showing a sixth embodiment of an integrated antenna module according to the present invention.

Two blocks of the PCB 93 having the non-square patch antenna 81 of the dielectric block according to the present embodiment and the PCB 94 having the GPS engine module 91 attached thereto are connected to each other using a coaxial cable 95. do. In this case, both PCB stages may have a rectangular shape, but the present invention is not limited thereto. The PCB may be replaced with a flexible PCB. According to the antenna module of such a configuration, the PCB stage 94 to which the GPS engine module 91 is attached has an advantage of free 360 ° rotation. That is, when spatial constraints and bending in the receiver are required according to the use of the coaxial cable, not only the antenna module may be implemented as shown in FIGS. 14A to 14C, but the present invention is not limited thereto. It is possible.

In this case, the GPS engine module may be implemented as an integrated unit of a low noise amplifier and a miniaturized GPS engine, a GPS engine itself without a low noise amplifier, or a band pass filter and a GPS engine. Therefore, those skilled in the art can design the GPS engine module as needed, and in general, it is preferable to integrate a miniaturized GPS engine, a band pass filter, and a low noise amplifier of one stage.

In the above described and described with respect to preferred embodiments of the present invention, the present invention is not limited to the specific embodiments described above, in the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims. For example, the amplifier is not limited to the integrated antenna module or the integrated GPS antenna engine module according to the present invention, but the ground noise is shielded from the low noise amplifier stage or the GPS engine module with a conductive material to prevent noise and oscillation of the antenna. In this case, the noise effect on the antenna can be reduced.

The non-square patch antenna of the dielectric block and the integrated antenna module using the same according to the present invention can be mounted inside the user equipment as a miniaturized antenna or antenna module than the commercially available square patch antenna and has an effect of improving reception performance.

That is, if the non-square patch antenna according to the present invention having the characteristics of linear polarization is used, the reception performance can be compensated for by improving signal processing of an engine such as SIRstar 3, but weak in a multipath signal (noise). The same antenna can be used regardless of star polarization, and the antenna module can be mounted inside the terminal by miniaturizing the size of the antenna module compared to the conventional square patch antenna.

In addition, by forming a conductive pattern on the side of the dielectric block of the non-square patch antenna according to the present invention that is different from the horizontal and vertical, it has a circular polarization characteristic or a non-square dielectric block using a high dielectric constant of 30 or more and the length of the short axis When extending more than 12mm by forming a conductive pattern on the top of the dielectric block can have a circular polarization characteristics.

In addition, for a dielectric block designed to be installed on an inner side of a wireless communication device, when the width of the dielectric block is less than a predetermined value (for example, 13 mm), the conductive pattern is designed to have linear polarization characteristics, and the width thereof is If more than (eg, 13mm ~ 15mm or more), by designing a conductive pattern to have a circular polarization characteristic can maximize the performance of the antenna signal receiving antenna of the dielectric block implemented in a non-square.

In addition, the non-square patch antenna of the dielectric block, which improves the characteristics of the linear polarization according to the adjustment of the size of the conductive pattern, is also a miniaturized antenna than the conventional square patch antenna, can be mounted inside the user equipment and has an improvement in reception performance. .

In addition, if one or more grooves are formed in the conductive pattern of the dielectric top surface of the non-square patch antenna, the width of the conductive pattern is narrowed, so that the characteristics of other linearly polarized antennas in the 1.8 GHz band gradually move to the low frequency and the other low frequency. It is close to the linearly polarized antenna of, and its frequency, magnitude, and phase angle are 90 °, which shows circular polarization characteristics.

In particular, when the non-square patch antenna has a circular polarization characteristic, the reception characteristics of the conventional square patch antenna can be reduced while maintaining the advantages of circular polarization with low polarization loss. As manufacturing becomes easier, the disadvantages can be solved while taking advantage of the conventional square patch antenna.

Next, an integrated antenna module for implementing the non-square patch antenna on a low noise amplifier and a single PCB, and an integrated GPS antenna engine module for implementing the non-square patch antenna on a single PCB may also be a conventional square patch antenna. While maintaining the reception performance of the present invention, it is possible to solve the design problem of the conventional terminal by positioning the inside of the user equipment according to the miniaturization.

Furthermore, the integrated antenna module or the integrated GPS antenna engine module may not only be positioned parallel to the horizontal direction at the upper end of the user equipment, but may be slightly bent or inclined depending on the terminal design, thereby enabling various applications.

1 is an exploded view showing the structure of a patch antenna device according to the prior art as the top and bottom surfaces,

2 is a view showing a navigation having a patch antenna according to the prior art,

3A is an exploded view showing the top, side, and bottom surfaces of the first embodiment of the non-square patch antenna of the dielectric block according to the present invention;

3B is an exploded view showing a top surface, a side surface, and a bottom surface of a second embodiment of the non-square patch antenna of the dielectric block according to the present invention;

3C is an exploded view illustrating a top surface and a bottom surface of a third embodiment of the non-square patch antenna of the dielectric block according to the present invention;

4A is an exploded view showing the top, side, and bottom surfaces of a fourth embodiment of a non-square patch antenna of a dielectric block according to the present invention;

4B is an exploded view illustrating the top, side, and bottom surfaces of a fifth embodiment of the non-square patch antenna of the dielectric block according to the present invention;

Figure 4c is a view showing a sixth embodiment of the non-square patch antenna of the dielectric block according to the present invention,

5 is an exploded top and bottom views illustrating a seventh embodiment of a non-square patch antenna of a dielectric block according to the present invention;

6 is a view showing a first embodiment of an integrated antenna module according to the present invention,

7 is a block diagram of a low noise amplifier used in the integrated antenna module according to the present invention,

8 is a view showing a second embodiment of an integrated antenna module according to the present invention;

9 is a view showing a third embodiment of the integrated antenna module according to the present invention;

10A to 10C are diagrams illustrating a characteristic implementation using a third embodiment of the present invention.

11 is a view showing a fourth embodiment of the integrated antenna module according to the present invention;

12 is a view showing a fifth embodiment of the integrated antenna module according to the present invention;

13 is a view showing a sixth embodiment of an integrated antenna module according to the present invention;

14A to 14C are diagrams illustrating a characteristic implementation using a sixth embodiment of the present invention.

Claims (15)

delete delete delete delete delete A dielectric block installed at an inner side of a wireless communication device for receiving satellite signals, the dielectric block being formed in a non-square with a different ratio of width and length; A conductive pattern applied in an upper end of the dielectric block and having a horizontal and vertical ratio differently adjusted according to characteristics of the satellite signal; And An input / output terminal electrically connected to the conductive pattern of the dielectric block and electrically separated from the ground surface of the lower end of the dielectric block through the dielectric block; The conductive pattern has a linear polarization characteristic by adjusting the length in the direction of the long axis of the dielectric block. Non-square patch antenna for satellite signal reception. The method of claim 6, The dielectric block is formed with a groove penetrating from the upper end to the lower end, The input / output terminal is a non-square patch antenna for receiving a satellite signal having a linearly polarized characteristic, characterized in that the feeding pin through the groove exposed to the lower end of the dielectric block. The method of claim 6, The dielectric block is formed with a groove penetrating from the upper end to the lower end, The input and output terminals have a linear polarization characteristic, characterized in that formed in the groove is filled with a conductive material containing silver (Ag) Non-square patch antenna for satellite signal reception. A dielectric block installed at an inner side of a wireless communication device for receiving satellite signals, the dielectric block being formed in a non-square with a different ratio of width and length; A conductive pattern applied in an upper end of the dielectric block and having a horizontal and vertical ratio differently adjusted according to characteristics of the satellite signal; And And an input / output terminal formed at the lower end of the dielectric block so as to be electrically separated from the upper conductive pattern of the dielectric block and the ground surface of the lower end of the dielectric block. The conductive pattern has a linear polarization characteristic by adjusting the length in the direction of the long axis of the dielectric block. Non-square patch antenna for satellite signal reception. 10. The method of claim 9, It further comprises a matching pattern formed on the upper end or side of the dielectric block for matching with the input and output terminals Non-square patch antenna for satellite signal reception. The method according to any one of claims 6 to 10, The dielectric block has a linear polarization characteristic, characterized in that the relative dielectric constant is formed in the range of 6 to 60. Non-square patch antenna for satellite signal reception. The method according to any one of claims 6 to 10, The dielectric block has a non-square patch antenna for receiving a satellite signal having a linear polarization characteristic, characterized in that the length of the short axis direction 13mm. The method according to any one of claims 6 to 10, The dielectric block has a non-square patch antenna for receiving a satellite signal having a linearly polarized characteristic, characterized in that the short axis of the length 10mm. The method according to any one of claims 6 to 10, The non-square patch antenna for receiving a satellite signal having a linear polarization characteristic, characterized in that the length of the dielectric block in the longitudinal direction of 35 mm. The method according to any one of claims 6 to 10, The length of the short axis direction of the dielectric block is a non-square patch antenna for receiving a satellite signal having a linear polarization characteristic, characterized in that less than the electrical length of the satellite signal for the dielectric block.

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