KR20070079761A - Antenna module for satellite communication in portable radio communication device - Google Patents

Abstract

The present invention relates to an antenna module for satellite communication in a portable wireless communication device, and more particularly, to a mounting position or a receiving direction when receiving a satellite signal such as GPS or satellite DMB (Digital Multimedia Broadcasting System) in a mobile and portable communication terminal. The present invention relates to an antenna module for satellite communication in a portable wireless communication device capable of stable signal reception without limitation.

According to the present invention, the antenna module and the feeder substrate unit is manufactured separately, so that the implementation of the antenna module is simple and easy to apply the product. It is possible to realize the desired beam width by adjusting and to configure the circuit configuration such as the amplifier in the same substrate, it is possible to implement a simple structure and various types of antenna module.

Description

Antenna module for satellite communication in mobile wireless communication device

1 is a reference diagram showing a conventional patch antenna for satellite communication,

2 is a structural diagram showing a conventional helical antenna,

3 is a structural diagram showing a conventional QHA type antenna;

4 is a reference diagram showing a configuration of a QHA type antenna according to FIG.

5 is a structural diagram showing an antenna module according to an embodiment of the present invention;

6 is a configuration diagram showing various configuration forms of the antenna module according to FIG. 5;

7 is a configuration diagram showing various forms of a structure in which a low noise amplifier is coupled to an antenna module according to FIG. 5;

8 is a first structural diagram showing a combination of an antenna unit and a feeder substrate unit of the antenna module according to FIG. 5;

9 is a second structural diagram showing a combination of an antenna unit and a feeder substrate unit of the antenna module according to FIG. 5;

10 is a reference diagram showing a mounting form of the antenna module according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

51 antenna portion 52 antenna pattern

53 feeder substrate portion 55 housing

57: low noise amplifier 59: connector

83: lock key 85: antenna assembly groove

95: lock key 97: antenna assembly socket

The present invention relates to an antenna module for satellite communication in a portable wireless communication device, and more particularly, to a mounting position or a receiving direction when receiving a satellite signal such as GPS or satellite DMB (Digital Multimedia Broadcasting System) in a mobile and portable communication terminal. The present invention relates to an antenna module for satellite communication in a portable wireless communication device capable of stable signal reception without limitation.

Globally, the satellite-based broadcasting, telecommunications, and internet industries are exploding, and are becoming the core medium of the information society in the 21st century. The satellite broadcasting receiving equipment industry has already been developed, including satellite antennas, and this is especially noticeable in the recent GPS field and satellite DMB field. In addition, with the development of semiconductors and the development of communication technologies, as the size and size of the devices become smaller and lighter, their application ranges become wider, and the use of such devices as GPS and DMB reception functions in vehicles as well as personal portable devices is becoming more common.

As a representative example of an antenna for receiving a conventional satellite signal, a patch antenna refers to an antenna having a planar shape as shown in FIG. 1, and an antenna circuit is formed in a plane. This conventional method is advantageous in that it is small, light, inexpensive, and easy to integrate, but due to the characteristics of the directional antenna, the front of the antenna should always be installed upward to receive satellite signals. There was a disadvantage that there are many installation restrictions, such as to be mounted. This installation limitation has a limitation in design application, and when carrying, there is a problem that the reception level may drop due to friction, accessories, and mounting positions.

What has emerged as an antenna to compensate for this problem is a QHA (Quadrifilar Helix Antenna) using a conventional helix antenna. FIG. 2 shows the structure of a helical antenna. As shown, the helical antenna refers to an antenna which is wound around a coil 21 having a spring shape electrically having a length of λ / 4 wavelength, and spirals to a center conductor of a coaxial feeder. The outer conductor of the coaxial cable 23 is connected to the ground plane 25 in the form of an antenna. Helical antenna has the advantage that can be implemented in a much smaller size than the dipole antenna and monopole antenna at the same frequency.

3 illustrates a conventional QHA type antenna structure, which is a type of antenna used for satellite communication in a mobile wireless communication device such as a mobile communication terminal or a GPS receiver. The antenna provides circularly polarized radiation and can be designed to have a quarter-wave or half-wavelength structure with shorted ends. Referring to the drawings, the QHA forms the ground section 35 to form the feed section 31 and the short circuit section 37 and to electrically connect therebetween. Comprising four radiating elements 33 electrically connected to one side of the feed section and the short circuit section, the feed section is arranged to feed the four radiating elements with a phase difference of 90 degrees to provide a circularly polarized radiation pattern .

The QHA type antenna device may be implemented as shown in (a) and (b) of FIG. 4, wherein (a) is a structure in which an antenna pattern is printed and etched on a ceramic cylindrical dielectric. Difficult to implement antenna pattern during development and production and difficult frequency tuning, making it difficult to tune new frequency when installing new products, and there is a limit of design application due to the use of fixed frequency antenna. In addition, there is a problem of cost burden as a structure to feed by using a balun (balun) or coaxial matching. (b) is a structure made by printing an antenna and a feeder on a Teflon or a thin thin film, and because Teflon is relatively expensive, there is a cost burden, and the dielectric constant is low, resulting in a large size.

QHA type antenna using the helical antenna as described above is currently being developed and distributed, which has a small and compact structure compared to the dipole antenna and the patch antenna, and is relatively less sensitive to handling and ground effects, and can easily form a radiation pattern and It has the advantage of having a broad circularly polarized beam. However, there is a problem in that the structure is complicated and frequency matching is difficult, and in particular, the reception frequency tuning is difficult in changing the frequency according to the surrounding environment when applying the receiver product. In addition, there is a limit to the application of product design because of the form of a fixed structure.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, an object of the present invention is to receive a satellite signal regardless of the mounting position and the receiving direction of the antenna to enable a stable signal reception during the movement An antenna module for satellite communication in a portable wireless communication device is provided.

In addition, another object of the present invention is to separate the antenna and the feeder substrate to make it easy to change the frequency and easy to apply and install when developing a new product.

In addition, another object of the present invention is to provide a simple structure and easy to implement and to implement various types of antenna module.

In order to achieve the above object, an antenna module for satellite communication in a portable wireless communication device of the present invention includes: an antenna unit for forming four or more helical antenna patterns having a specific polarity in a cylindrical pillar-shaped dielectric; A feeder substrate unit constituting a feeder for supplying electrical energy to the antenna unit and a matching circuit for performing impedance matching to the antenna unit; And a housing forming an outer shape of the antenna unit and the feeder substrate unit.

Hereinafter, an antenna module for satellite communication in a portable wireless communication device for receiving a satellite signal according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 5 schematically shows the configuration of an antenna module according to an embodiment of the present invention, Figure (a) shows a basic antenna module structure according to the present invention and Figure (b) is in the antenna module of Figure (a) It shows a structure in which a low noise amplifier (LNA) is additionally configured.

The antenna unit 51 includes four helical antenna patterns 52 having a specific polarity of right hand circular polarization (RHCP) or left hand circular polarization (LHCP) on a dielectric having a cylindrical shape having a high dielectric constant such as ceramic or alumina. It is implemented by printing or etching. In this case, the helical antenna pattern may be implemented to have four or more. When implemented with four or more antenna patterns, the helical antenna pattern may be applied to a dual band antenna that may improve the gain of the antenna and simultaneously receive two reception frequencies. The antenna unit forms only an antenna pattern, and through the pattern structure, frequency can be matched by matching polarization of a received signal and adjusting the length of the pattern. At this time, the antenna portion preferably uses a ceramic or alumina having a high dielectric constant as the cylindrical dielectric material, thereby miniaturizing the antenna portion.

The feeder substrate portion 53 forms a feeder and a matching circuit thereon using a printed circuit board (PCB). The feeder serves to provide electrical energy to the antenna unit 51 and is designed to have a phase array 4 input structure having a phase difference of 90 degrees and implemented on the substrate. More specifically, the feeder has a phase difference of 0, 90, 180, and 270 degrees. The feeder is designed to be designed on the substrate in accordance with the frequency and impedance characteristics to be designed in consideration of the dielectric constant of the substrate and the characteristics of the substrate. The final antenna module is fabricated by implementing the input / output matching circuit of the antenna on the substrate, and assembling and combining the feeder substrate portion in which the feeder and the matching circuit are designed as described above. At this time, the matching circuit serves to match a specific impedance of the antenna unit with respect to the impedance of the transmitting and receiving apparatus.

In addition, as shown in (b) of FIG. 5, the antenna module may further configure a low noise amplifier 57 in the feeder substrate to amplify the received signal. Low noise amplifiers (LNAs) require amplification because signals received from satellites have very low power levels due to the effects of attenuation and noise, which minimize and amplify the noise.

The feeder substrate unit may be implemented using a double-sided or a multi-layered substrate, and the substrate may be used in various ways depending on the structure or form of the amplifier or receiver module interworking with the antenna and the substrate using the receiver. In case of impedance matching only, any substrate can be used regardless of the type of substrate, and it is manufactured by using alumina and epoxy to achieve miniaturization of size. Can be.

The housing 55 forms an outer shape of the antenna module including the antenna unit and the feeder substrate unit, and the antenna module including the antenna unit, the feeder substrate unit and the low noise amplifier. In addition, when the low noise amplifier is further configured as shown in FIG. In addition, the connector 59 is provided on one surface of the housing in contact with the low noise amplifier to output the signal of the low noise amplifier. The housing packages the antenna module so that the antenna module of the present invention performs independent operation irrespective of external influences and can be easily used by simply taking it and assembling it.

As described above, the antenna unit and the feeder substrate unit are designed and manufactured, respectively, and assembled by combining the antenna unit by simply implementing the input / output matching circuit of the antenna unit on the substrate of the feeder substrate unit. More specifically, the final antenna is fabricated by implementing the input / output matching circuit of the antenna on the substrate constituting the feeder, and a low noise amplifier for amplifying the received signal is generally divided into the antenna part, the feeder substrate part, and the part of the amplifier. Can be. Designing a feeder with a specific frequency during manufacturing and tuning is completed, then frequency tuning is possible only by adjusting the pattern length of the antenna, which makes it possible to tune the frequency according to the product and surrounding circuits, thus simplifying the application of the antenna to the receiver. . The feeder can be designed and applied for each frequency of use, so even if the characteristics or materials of the board are changed, the feeder can be redesigned according to the characteristics, making product implementation easier.

In the antenna module of the present invention, the antenna unit and the feeder substrate unit may be implemented with various configurations. 6 and 7 illustrate various configurations of the antenna module, and FIG. 6 illustrates a coupling structure of the antenna unit and the feeder substrate as a basic antenna module, and FIG. 7 further includes a low noise amplifier in the basic antenna module. The various combination structures of the antenna unit, the feeder substrate unit, and the low noise amplifier are shown.

As shown in FIG. 6 and FIG. 7, various types of antenna modules may be implemented by being grounded compared to a conventional patch antenna when mounted on a mobile receiver such as a small satellite receiver, a PDA, a PC, a small LCD navigation system, and a mobile phone. The characteristics of the antenna are less sensitive, which increases the operating range of the mounting. In addition, when applied to a small terminal, the size of the antenna is small, and the product can be miniaturized, and it is possible to apply a variety of product designs as the influence of mounting is insignificant in the product design. FIG. 10 shows a mounting form of an antenna module, and FIGS. (A) and (b) show an external antenna mounting form and an internal antenna mounting form, respectively. As shown, the antenna module of the present invention may be configured in various forms. More specifically, the feeder board unit, the amplifier and the receiving engine can be implemented on the same board, and the antenna unit can be configured separately from the antenna unit, so that the antenna module can be configured in various forms such as date, tracer or circular and square. This makes it easy to apply and install a variety of designs, and therefore has a wide range of applications.

The antenna unit and the feeder substrate unit have a structure as shown in FIGS. 8 and 9 for efficient and stable fixing and mounting of the antenna unit and the feeder substrate unit. 8 and 9 illustrate a fixed coupling structure of the antenna unit and the feeder substrate, respectively. In FIG. 8, the antenna unit forms a locking key 83 having an uneven shape on the lower surface of the cylindrical dielectric 81. In this case, the lock keys are formed to correspond to the positions of the four helical antenna patterns 82, respectively. The feeder board unit 89 forms an antenna assembly groove 85 at a position corresponding to each lock key for assembling the lock key of the antenna unit, and the antenna lock key is engaged with the antenna assembly groove. The part and the feeder substrate part are fixedly coupled.

In the case of Figure 9, for coupling the antenna unit and the feeder substrate portion, the antenna portion is formed on the lower surface of the cylindrical dielectric 91 to form the locking key 95 of the concave-convex shape so as to correspond to the four helical antenna pattern 93, respectively, The board portion 99 forms an antenna assembly socket 97 at a position corresponding to each lock key for coupling with the lock key so that the lock key of the antenna portion can be inserted into and fixed to the antenna assembly socket. .

After the fixed coupling of the antenna unit and the feeder board unit, the antenna pattern having the same shape as the four helical antenna patterns is implemented on the feeder board unit to implement the antenna characteristics collectively, and reduce the phase error through the precise combination of the antenna unit and the feeder board unit. Can be.

The antenna module according to the present invention implements a variety of antenna patterns to manufacture a small QHA type antenna to be implemented by tuning the overall characteristics of the antenna, such as the radiation pattern and frequency and gain of the antenna, and in this way the number of antennas and satellites The antenna, feeder, amplifier, and receive tuner can be implemented on the same board by assembling the antenna to a new tuner or receiving engine, thereby securing price competitiveness due to size reduction, improved characteristics, stability against noise, and cost reduction. Antenna modules can be manufactured.

As described above, according to the antenna module for satellite communication in the portable wireless communication apparatus according to the present invention, the antenna module and the feeder substrate unit are manufactured separately, so that the implementation of the antenna module is simple and the product is easily applied.

In addition, the simple frequency change facilitates the development of antennas with new frequency bands, thus shortening product development time.

In addition, in the feeder substrate part, the feeder is combined with the antenna part using two or more multilayered boards to adjust the phase of the antenna to realize the desired beam width, and the structure of the circuit such as the amplifier can be configured in the same substrate, thereby simplifying the structure. And various types of antenna module can be implemented.

In addition, the characteristics of the antenna due to grounding are less sensitive, so the operating range of the mounting is wider, and in particular, when the small terminal is applied, the size of the antenna is small, so that the product can be miniaturized. It is possible.

Claims (9)

An antenna unit forming at least four helical antenna patterns having a specific polarity in a cylindrical pillar-shaped dielectric; A feeder substrate unit constituting a feeder for supplying electrical energy to the antenna unit and a matching circuit for performing impedance matching to the antenna unit; And A housing forming an outer shape of the antenna unit and the feeder substrate unit; Antenna module for satellite communication in a portable wireless communication device comprising a. The method of claim 1, And said feeder substrate further comprises a low noise amplifier for amplifying a received signal. The method according to claim 1 or 2, And the antenna unit is implemented using a dielectric having a high dielectric constant such as ceramic or alumina. The method of claim 3, The antenna unit is an antenna module for satellite communication in a portable wireless communication device, characterized in that the locking key formed in the concave-convex shape at a position corresponding to the four helical antenna patterns on the bottom of the dielectric of the cylindrical pillar and fixedly coupled to the feeder substrate. The method of claim 4, wherein The antenna unit is an antenna module for satellite communication in a portable wireless communication device, characterized in that to form an antenna pattern having a polarity of Right Hand Circular Polarization (RHCP) or Left Hand Circular Polarization (LHCP) on the outer surface of the cylindrical pillar. The method according to claim 1 or 2, And the feeder substrate unit forms an antenna assembly unit groove or an antenna assembly unit socket at a position corresponding to the lock key of the antenna unit, and fixes and couples the antenna unit to the antenna unit. The method of claim 6, The feeder substrate unit is an antenna module for satellite communication in a portable wireless communication device, characterized in that implemented using alumina, epoxy. The method of claim 6, The feeder substrate unit may be implemented as a double-sided or multi-layer substrate, the antenna module for satellite communication in a portable wireless communication device. The method of claim 6, The feeder substrate unit may be implemented using a variety of substrates of the circular, rectangular or polygonal antenna module for satellite communication in a portable wireless communication device.

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