PATCH ANTENNA HAVING PROGRAMMABLE FREQUENCY AND POLARIZATION

Abstract

The present invention relates to a patch antenna having programmable frequency and polarization comprising the first metal covering layer, the dielectric layer, the second metal covering layer and four metallized through-holes, each of which are disposed sequentially from top to bottom, wherein the first metal covering layer comprises the feeding line and the radiating patch; the feeding line comprises the micro-strip line, which can be connected to the outer feeding port; the micro-strip line is connected to one side of the radiating patch through the high-resistance line; the radiating patch is a square-shaped metal patch; a gap is etched near the other side of the radiating patch, namely, the radiating edge; the gap is parallel to the radiating edge.

Claims

1. A patch antenna having programmable frequency and polarization comprising: a first metal covering layer; a dielectric layer; a second metal covering layer; a first metallized through-hole; a second metallized through-hole; a third metallized through-hole, and a fourth metallized through-hole, all of which are disposed sequentially from top to bottom, wherein the first metal covering layer comprises the feeding line and the radiating patch, wherein the feeding line comprises a micro-strip line, which can be connected to the outer feeding port, wherein the micro-strip line is connected to one side of the radiating patch through a high-resistance line, wherein the radiating patch is a square-shaped metal patch, wherein a gap is etched near the other side of the radiating patch, namely, the radiating edge, wherein the gap is parallel to the radiating edge, wherein the first metallized through-hole, the second metallized through-hole, the third metallized through-hole and the fourth metallized through-hole are disposed at the two sides of the bended part of the gap, wherein the two ends of the four metallized through-holes are respectively connected to the first metal covering layer and the second metal covering layer, wherein the first metallized through-hole, the second metallized through-hole, the third metallized through-hole and the fourth metallized through-hole are provided with switches respectively, wherein when a switch is switched on, the first metal cover layer is connected to the second metal covering layer through the metallized through-hole controlled by this switch.

2. The patch antenna having programmable frequency and polarization of claim 1, wherein the middle part of the gap is U-shaped, which is connected end-to-end, and the U-shaped edge is perpendicular to the radiating edge.

3. The patch antenna having programmable frequency and polarization of claim 1, wherein the dielectric layer and the second metal covering layer have the same size and are square-shaped, of which the area is bigger than that of the first metal covering layer.

4. The patch antenna having programmable frequency and polarization of claim 1, wherein the switch is a PIN diode switch, MEMS switch or mechanical metal-connecting switch.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] FIG. 1 is a structure diagram of the antenna having programmable frequency and polarization of the present invention.

[0014] FIG. 2 is a structure diagram of the first metal covering layer of the embodiment of the present invention.

[0015] FIG. 3 is a schematic diagram of the gap and the switch of the embodiment.

MARKING INSTRUCTIONS OF THE DRAWINGS

[0016] 1. The First Metal Covering Layer, 2. The Dielectric Layer, 3. The Second Metal Covering Layer, 41. The First Metallized Through-hole, 42. The Second Metallized Through-hole, 43. The Third Metallized Through-hole, 44. The Fourth Metallized Through-hole, 5. Micro-strip Line, 6. High-resistance Line, 7. Gap

DETAILED DESCRIPTION OF THE INVENTION

[0017] Drawings and detailed embodiments are combined hereinafter to elaborate the technical principles of the present invention.

[0018] As shown in FIG. 1, the patch antenna having programmable frequency and polarization comprises the first metal covering layer 1, the dielectric layer 2, the second metal covering layer 3, the first metallized through-hole 41, the second metallized through-hole 42, the third metallized through-hole 43 and the fourth metallized through-hole 44, each which are disposed sequentially from top to bottom. The first metal covering layer 1 comprises the feeding line and the radiating patch. The feeding line comprises the 50Ω micro-strip line 5, which can be connected to the outer feeding port. The micro-strip line 5 is connected to one side of the radiating patch through the high-resistance line 6. The radiating patch is a square-shaped metal patch. A gap 7 is etched near the other side of the radiating patch, namely, the radiating edge. The gap 7 is parallel to the radiating edge; the middle part of the gap is U-shaped, which is connected end-to-end. The U-shaped edge is perpendicular to the radiating edge. The first metallized through-hole 41, the second metallized through-hole 42, the third metallized through-hole 43 and the fourth metallized through-hole 44 are disposed at the two sides of the bended part of the gap 7. The two ends of the metallized through-holes are respectively connected to the first metal covering layer 1 and the second metal covering layer 3. The first metallized through-hole 41, the second metallized through-hole 42, the third metallized through-hole 43 and the fourth metallized through-hole 44 are provided with switches respectively. When a switch is turned on, the first metal cover layer 1 is connected to the second metal covering layer 3 through the metallized through-hole controlled by this switch. The switch is preferred to be a PIN diode switch. The dielectric layer 2 and the second metal covering layer 3 are square-shaped and the same size, of which the area is bigger than that of the first metal covering layer 1. Additionally, the length and width of the high-resistance line 6 can be regulated.

[0019] The principle of the technical solution of the present invention is to regulate the length and the width of the above high-resistance line 6 so as to match the different input resistance. Meanwhile, the loading switch can improve the resistance matching, producing optimal high frequency synchronization and improving the mismatching of the low frequency by the switch. The location of the above bended gap 7 is near the radiating edge of the patch. For TM.sub.100 mode, the radiating edge of the patch is zero current so that the gap 7 has a small interference on the current. With respect to the TM.sub.200 mode, the current of the location of the gap 7 is higher and the location of the gap 7 is perpendicular to the direction of the resonance current, resulting in a large amount of interference on the current. When the length and location of the gap 7 are proper, one of the half-wavelength resonance areas can be reduced. Meanwhile, when the current moves around the gap 7, the far-field radiation generated by the device can be counteracted. The two wave beams of TM.sub.200 mode and the zero point in the middle can disappear and change into a wave beam similar to the TM.sub.100 mode. When the patch around the gap 7 is regarded as two U-shaped branches which are jointed together, the current can be regarded as the resonance on one branch under TM.sub.200 mode. For TM.sub.100 mode, this area can also be regarded as a U-shaped branch without resonance. The current path on the U-shaped branch is lengthened by the bended part in the middle of the gap, slightly reducing the working frequency.

[0020] With respect to the TM.sub.100 mode, when the switches S.sub.1, S.sub.3 and S.sub.4 are switched off and switch S.sub.2 is switched on, one end of the right branch near the interior of the patch is grounded through the switch, which is equivalent to load inductance on the end of the branch, thereby changing the phase of the surface current and forming the circular polarization. For the TM.sub.200 mode, the switch is equivalent to the inductive grounding. In this case, the inductance is a negative inductance, which is affected by the resonance current of the bottom half of the patch. Accordingly, the length of resonance is shortened. Compared with the condition that four switches are switched-off simultaneously, the high frequency moves upwards a little at the moment. When the switch S.sub.2, which is switched on, is replaced by Switch S.sub.1, the low frequency is changed from right-handed circular polarization to left-handed circular polarization. When switch S.sub.1, S.sub.2 are switched on and switch S.sub.3 S.sub.4 are switched off, for low frequency, the inductance is loaded on the left and right U-shaped branches symmetrically so that the phase difference of the surface current can be eliminated accordingly, producing the dual-frequency linear polarization working mode. Additionally, the mismatched low-frequency input resistance can be compensated and the low frequency synchronization can be improved without compromising high frequency functionality. When at least one of switch S.sub.3 or S.sub.4 is switched on, the TM.sub.100 mode is mismatched badly, leaving one working frequency of TM.sub.200 mode. However, for a different combination of switches, the working frequency can be different due to the different presentation of loading inductance. Therefore, frequency regulation can be produced by regulating the state of the switch. The working frequency is the resonance frequency of TM.sub.200 mode so that the linear polarization working state can be realized.

[0021] To further elaborate the practicality of the above technical solution, a detailed design is provided hereinafter. As shown in FIGS. 2 and 3, the dielectric substrate of the patch antenna having programmable frequency and polarization adopts a F4B substrate, of which the thickness is 2 mm and the dielectric constant is 2.55. The geometric parameter values of the corresponding antenna are: a=75 mm, b=36.8 mm, 11=6.9 mm, 12=12 mm, 13=31.4 mm, 14=26 mm, g=2.5 mm, p=2.4 mm, w=3.34 mm, d=1 mm, q=2.35 mm. The testing result shows that the working frequency of the antenna under the dual-frequency linear polarization working mode is 2.47 GHz and 4 GHz respectively. Additionally, the working frequency under the right-handed circular polarization-linear polarization working mode is 2.45 GHz and 3.89 GHz respectively, in which the axial ratio of 2.45 GHz is 0.86 dB. The working frequency of the antenna under the single-frequency working mode is shown in Table 1. In this arrangement, “1” and “0” means the switch is turned on and off respectively according to the coding rule of the working module. For instance, when switch S.sub.2 and S.sub.4 are switched on, the code of S.sub.1S.sub.2S.sub.3S.sub.4 is “0101”. The cross-polarization of the antenna under all of the frequencies is less than −15 dB.

TABLE-US-00001 TABLE 1 Working Frequency Working Frequency Working Frequency mode (GHz) mode (GHz) Mode (GHz) 0100 2.865 0101 3.021 0110 3 0111 3.06 1000 2.868 1001 2.868 1010 3.021 1011 3.06 1100 2.973 1101 3.141 1110 3.141 1111 3.198 [0022] The present invention also has the following advantages: [0023] (1) The working modes of the present invention are various, having linear polarization, left-handed circular polarization and right handed circular polarization under the dual-frequency working mode and nine different working frequencies under the single-frequency working mode; [0024] (2) The control is easy, requiring only four PIN diode switches; [0025] (3) The damage to the antenna's structure minimal, assuring optimal performance of the antenna in every working mode. [0026] The previous descriptions are of preferred examples for implementing the invention, and the scope of the invention should not necessarily be limited by this description. [0027] The scope of the present invention is defined by the claims.