WO2012116603A1 - Inverted-f antenna and mobile terminal - Google Patents

Abstract

Disclosed in the present invention is an inverted-F antenna, comprising a main radiation body of the inverted-F antenna disposed in the clear zone on the printed circuit board of a mobile phone in the manner of a serpentine line. The shape of a serpentine line is applied in the present invention to the inverted-F antenna, expanding its band width to a relatively large extent, and at the same time saving space of the antenna; the small volume and light weight thereof satisfy the requirement for delicate profiling in today's mobile phones. In addition, it has a simple structure and low cost, and it is easy to connect to other circuits and systems and to manufacture. It is expected to have a good application prospect and achieve a good economic benefit.

Description

 Inverted F antenna and mobile terminal

Technical field

 The present invention relates to the field of communications, and in particular, to an Inverted-F Antenna Inverted (IFA) and a mobile terminal. Background technique

 With the development of modern communication technologies, antennas, as front-end devices of communication systems, have received more and more attention and more improvements, especially in terms of bandwidth capacity. As for the mobile phone antenna, as people's aesthetic concepts change, the requirements for antenna modeling are getting higher and higher. As many mobile phones in the past are thicker and larger in size, this is a good state for the antenna, which allows the antenna to have more space, thicker thickness and better performance. But nowadays mobile phones are getting thinner and thinner, and the size of mobile phones is also very limited, especially for some ultra-thin and compact mobile phones for women, so the antenna is put forward higher requirements, in limited space and very short. Achieve superior performance at high altitudes.

 Compared with general microwave antennas, microstrip antennas have many advantages, such as low cost, light weight, simple processing, easy installation, and compatibility with integrated circuits. It is widely used in missile launchers, aircraft, phased array antennas, and portable wireless transceivers. However, it also has some shortcomings such as bandwidth and axial ratio. Generally, the bandwidth of a microstrip antenna is very narrow (less than 10%), and the fatal shortcoming makes the microstrip antenna unable to meet the needs of modern communication systems.

 There are several types of mobile phone antennas: PIFA (Planar Inverted-F Antenna Inverted), IFA (Inverted-F Antenna Inverted) and Monopole Antenna.

The PIFA antenna is deformed by the microstrip antenna, and the IFA antenna is deformed by the PIFA antenna, so the microstrip antenna has disadvantages. The IFA antenna also has.

For IFA antennas used in mobile phones, it is necessary to expand their bandwidth. At present, there are many ways to improve the bandwidth of microstrip antennas, such as increasing the height of the patch, using two radiating patches to achieve dual frequency, slotting the radiating patch to create two grounded resonant modes and using a tapered Radiation patch, etc. These methods can effectively improve the bandwidth of the microstrip antenna. Can also change the knot by the ground Construct to increase the antenna bandwidth, such as T-type ground, H-type ground.

 The above method of widening the bandwidth is limited by the space in the specific implementation, especially for a mobile phone with a small size, which is very difficult to implement. Summary of the invention

 It is an object of the present invention to provide an IFA antenna that addresses the shortcomings of the existing IFA antenna bandwidth.

 In order to solve the above problems, the present invention provides an inverted F antenna, including:

 The radiating body of the inverted-F antenna is arranged in a serpentine manner in the clearance area of the printed circuit board of the mobile terminal.

 Optional,

 The inverted F antenna is grounded at one end, and a point on the antenna is connected to the coaxial feed line.

 Optional,

 At least part of the line segments on the inverted F antenna have the same triangular structure, and two of the triangular structures are formed by a partial line segment of the inverted F antenna.

 Optional,

 The triangular structure is a right-angled triangular structure, and a part of the line segment of the inverted-F antenna constitutes a right-angled side and a hypotened side of the right-angled triangle.

 Optional,

 The direction of the line segment of the right-angled side of the right-angled triangle is perpendicular to the direction of the IFA antenna. Optional,

 The length of the inverted F antenna is one quarter of the operating wavelength of the antenna.

 Optional,

 The operating wavelength λ of the inverted F antenna is calculated by the following formula:

Where: c is the speed of light; f is the center frequency of the inverted F antenna; f is the printed circuit of the mobile phone The dielectric constant of the board.

 The present invention also provides a mobile terminal comprising an inverted F antenna as described above.

 The above scheme applies the shape of the serpentine line to the IFA antenna, which expands the bandwidth to a large extent, and also saves the antenna space, is small in size, and light in weight, and meets the needs of the compact size of the current mobile phone. In addition, the structure is simple, easy to connect with other circuits or systems, easy to manufacture, low in cost, and expected to have good application prospects and good economic benefits. BRIEF abstract

 Figure 1 is a side elevational view of an IFA antenna in accordance with an embodiment of the present invention;

 2 is a top plan view of an IFA antenna in accordance with an embodiment of the present invention. Preferred embodiment of the invention

 Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It should be noted that, in the case of no conflict, the features in the embodiments and the embodiments in the present application may be arbitrarily combined with each other.

 In this embodiment, the radiating body of the IFA antenna is arranged in a serpentine manner in a clearance area of a PCB (Printed Circuit Board) board of a mobile terminal such as a mobile phone. One end of the IFA antenna is grounded, and a point on the antenna is connected to the coaxial feed line. The length of the antenna is one quarter of the operating wavelength of the antenna; wherein the operating wavelength λ of the antenna is calculated by the following formula:

Where: c is the speed of light; f is the center frequency of the antenna; f is the dielectric constant of the PCB.

 In another embodiment of the present invention, the antenna is arranged in a clearance area of the mobile phone PCB board by means of a serpentine line, meaning that at least part of the line segments on the antenna have the same triangular structure, and two of the triangular structures The strip side is composed of a partial line segment of the antenna. Preferably, the triangular structure is a right-angled triangular structure, and a part of the line segment of the antenna constitutes a right-angled side and a hypotened side of the right-angled triangle, and the direction of the line segment constituting the right-angled side is perpendicular to the direction of the antenna.

The design parameters of the present invention are theoretical simulations and experimental results selected on the basis of a certain theoretical analysis, which show that the effect is good. The experimental results show that the antenna has a -10dB bandwidth of 50% and a working frequency range of 1.5GHz to 2.47GHz. Compared with the usual microstrip antenna, the bandwidth is less than 10%. 5 times, (testing other parameters) has a very large improvement, and the bandwidth improvement is more obvious. The details and operation of the specific device according to the present invention will be described in detail below with reference to FIG. It mainly includes: antenna radiation body 1, PCB board 2, PCB ground layer 3 and antenna grounding column 4. As shown in Fig. 2, the point where the IFA antenna is connected to the coaxial feeder is the antenna feed point B; the point where the IFA antenna is connected to the antenna ground column (4) is the ground point A, and the IFA antenna is grounded through the ground point A.

 The antenna radiating body having the serpentine line structure is placed in the clearance area of the rectangular PCB board, wherein the size of the PCB board is Ll*L2=40 mm x 90 mm, the thickness is 1 mm, and the length of the clearance area is L3=12 mm. The distance from the location A to the feed point B is b = 4 mm, where the length of the ground arm is a = 5 mm. Here, a total of four deformed right-angled triangular structures are used. In each right-angled triangular structure, c = 2 mm, d = 3 mm, and the length of the deformed serpentine line determines the operating frequency band of the antenna.

 The test results show that when the IFA antenna is arranged in a serpentine line, the bandwidth improvement is more obvious. The total volume is 90mm*40mm* 1.4mm and weighs less than 150g.

 The above description is only a preferred embodiment of the present invention and is not intended to limit the scope of protection of the present invention. In view of the present invention, various other modifications, equivalents, improvements, etc., should be made without departing from the spirit and scope of the invention. It is included in the scope of protection of the present invention.

Industrial applicability

 The above embodiment applies the serpentine shape to the IFA antenna, which expands the bandwidth to a large extent, and also saves the antenna space, is small in size, and light in weight, and meets the needs of the compact size of the current mobile phone. In addition, the structure is simple, easy to connect with other circuits or systems, easy to manufacture, low in cost, and expected to have good application prospects, and achieve good economic benefits.

Claims

Claim  1. An inverted F antenna, characterized in that:  The radiating body of the inverted-F antenna is arranged in a serpentine manner in the clearance area of the printed circuit board of the mobile terminal.  2. The inverted F antenna of claim 1 wherein:  The inverted F antenna is grounded at one end, and a point on the antenna is connected to the coaxial feed line.  3. The inverted F antenna of claim 1 wherein:  At least part of the line segments on the inverted F antenna have the same triangular structure, and two of the triangular structures are formed by a partial line segment of the inverted F antenna.  4. The inverted F antenna of claim 3, wherein:  The triangular structure is a right-angled triangular structure, and a part of the line segment of the inverted-F antenna constitutes a right-angled side and a hypotened side of the right-angled triangle.  5. The inverted F antenna of claim 4, wherein:  The direction of the line segment of the right-angled side of the right-angled triangle is perpendicular to the direction of the IFA antenna.  6. The inverted F antenna of claim 1 wherein:  The length of the inverted F antenna is one quarter of the operating wavelength of the antenna.  7. The inverted-F antenna of claim 6, wherein:  The operating wavelength λ of the inverted F antenna is calculated by the following formula: Where: c is the speed of light; f is the center frequency of the inverted F antenna; f is the dielectric constant of the printed circuit board of the mobile terminal.  The inverted F antenna according to any one of claims 1 to 7, wherein the mobile terminal is a mobile phone.  A mobile terminal comprising the inverted-F antenna according to any one of claims 1-7.