MxN MILLIMETER WAVE AND TERAHERTZ PLANAR DIPOLE END-FIRE ARRAY ANTENNA

Abstract

The present disclosure belongs to the field of radio frequency circuit design, and in particular relates to a M×N millimeter wave and terahertz planar dipole end-fire array antenna. The M×N millimeter wave and terahertz planar dipole end-fire array antenna is composed of M paths of N× end-fire linear array antennas arranged at equal intervals, and the distance d between two adjacent N× end-fire linear array antennas is less than λ, where λ is the wavelength, and both M and N are integers greater than 1. By connecting linear type feed networks of the M paths of N× end-fire linear array antennas to M-path in-phase radio frequency signal transmitter and controlling the distance between two adjacent N× end-fire linear array antennas to be less than the effective wavelength, a higher gain and a higher half-power width can be realized, and the power consumption of the transmitter can be reduced.

Claims

1. A M×N millimeter wave and terahertz planar dipole end-fire array antenna, comprising M paths of N× end-fire linear array antennas arranged at equal intervals, wherein the distance d between two adjacent N× end-fire linear array antennas is less than λ, wherein λ, is the wavelength, and both M and N are integers greater than 1; wherein each of the N× end-fire linear array antennas is of a planar structure, comprising a linear type feed network, and N dipole antenna elements constituting the N× end-fire array antenna; and the linear type feed networks in the M paths of N× end-fire linear array antennas are connected to a M-path in-phase radio frequency signal transmitter.

2. The M×N millimeter wave and terahertz planar dipole end-fire array antenna according to claim 1, wherein the antenna element is a dipole antenna.

3. The M×N millimeter wave and terahertz planar dipole end-fire array antenna according to claim 1, wherein one end of the linear type feed network is connected to the M-path in-phase radio frequency signal transmitter via matched micro-strip lines or coplanar waveguides.

4. The M×N millimeter wave and terahertz planar dipole end-fire array antenna according to claim 1, wherein a number of the antenna elements is 3 to 20, and a distance Δd between two adjacent antenna elements is equal to λ(2k), wherein k is an integer greater than zero.

5. The M×N millimeter wave and terahertz planar dipole end-fire array antenna according to claim 4, wherein the antenna elements are etched on a same metal surface and are towards a same side.

6. The M×N millimeter wave and terahertz planar dipole end-fire array antenna according to claim 4, wherein the number of the antenna elements connected to a same upper feed network or a same lower feed network is 3 to 20, and the distance Δd between the two adjacent antenna elements is equal to λ(2k), wherein k is an integer greater than zero.

7. The M×N millimeter wave and terahertz planar dipole end-fire array antenna according to claim 4, wherein a number M of the N× end-fire linear array antennas is 2 to 100.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] FIG. 1 is a schematic diagram of a planar process-based N×(N=5) half-wave dipole end-fire linear array antenna.

[0019] FIG. 2 is a schematic diagram of a 4×5 millimeter wave and terahertz planar dipole end-fire array antenna constructed when the number of the array elements is that M=4 and N=5.

[0020] FIG. 3 is a diagram of a three-dimensional structure of a Rogers4350 process-based 4×5 millimeter wave and terahertz dipole end-fire linear array antenna constructed when the number of the array elements is that N=5.

[0021] FIG. 4 is a design diagram of upper metal of a Rogers4350 process-based 4×5 millimeter wave and terahertz dipole end-fire linear array antenna constructed when the number of the array elements is that N=5 and k=2.

[0022] FIG. 5 is a design diagram of bottom metal of a Rogers4350 process-based 4×5 millimeter wave and terahertz dipole end-fire linear array antenna constructed when the number of the array elements is that N=5 and k=2.

[0023] FIG. 6 is a first embodiment of a four-path in-phase radio frequency signal transmitter.

[0024] FIG. 7 is a second embodiment of a four-path in-phase radio frequency signal transmitter.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0025] The present disclosure is further explained and described below with reference to the accompanying drawings and embodiments.

[0026] A M×N millimeter wave and terahertz planar dipole end-fire array antenna provided by the present disclosure is achieved by using a planar process, such as a PCB (printed circuit board) process, SiGe BiCMOS (bipolar complementary metal oxide semiconductor) process, and a CMOS (complementary metal oxide semiconductor) process. At first, a N× end-fire linear array antenna suitable for the planar process is designed, as shown in FIG. 1. An antenna element of the N× end-fire linear array antenna may employ various antenna structures such as a dipole antenna, a helical antenna, and a patch antenna, then a M-path N× end-fire linear array antenna structure is further constructed, as shown in FIG. 2, the M-path of N× end-fire linear array antennas are arranged at equal intervals, the distance d between two adjacent N× end-fire linear array antennas is less than λ, where λ, is the wavelength, and both M and N are integers greater than 1.

[0027] The N× end-fire linear array antenna comprises a linear type feed network, and N dipole antenna elements constituting the N× end-fire array antenna. The linear type feed networks in the M paths of N× end-fire linear array antennas are connected to a M-path in-phase radio frequency signal transmitter.

[0028] By taking the Rogers4350 process-based 4×5 millimeter wave and terahertz end-fire linear array antenna as an example, the structure and fabrication process of the end-fire linear array antenna are introduced.

[0029] As shown in FIG. 3, four paths of 5× end-fire linear array antennas are arranged at equal intervals to form a 4×5 millimeter wave and terahertz end-fire linear array antenna, which is fabricated by using the Rogers4350 process and is directly printed on a PCB with double metal surface, where a half-wave dipole element serves as the antenna element.

[0030] As shown in FIG. 4, feed networks are etched on the upper and lower metal of the PCB board with double metal surface, five antenna elements perpendicular to an upper feed network are etched on the same side of the upper feed network, and five antenna elements perpendicular to a lower feed network are etched on the same side of the lower feed network. The lower antenna elements face the opposite direction to the antenna elements on the upper feed network, and each group of upper and lower metallic antenna elements facing opposite directions form a half-wave dipole antenna element. The distance Δd between the two adjacent half-wave dipole antenna elements is equal to λ(2k), and the distance Δd may be fine-tuned up and down from λ/(2k), and in FIG. 4, k is equal to 2.

[0031] In the embodiment, the M×N terahertz planar dipole end-fire array antenna is subjected to feed through M paths of in-phase radio frequency signals, and the M paths of in-phase radio frequency signals may be achieved by designed a M-path in-phase terahertz transmitter.

[0032] FIG. 6 provides a structure of a four-path in-phase terahertz transmitter. By taking an operating frequency of 244 GHz as an example, the transmitter comprises an oscillation source, a power amplifier, power dividers, and frequency multipliers. A radio frequency signal transmitted by the oscillation source is input to one power divider after passing through the power amplifier, and then is divided into two by another power divider; each of the two separate signals is divided into two again by a power divider. So far, one signal is divided into four paths of in-phase radio frequency signals, and the four paths of in-phase radio frequency signals are configured to feed all the N× end-fire linear array antennas respectively after passing through the frequency multipliers. In accordance with the embodiment, the frequencies of the oscillation source, the power amplifier and the power divider are all 122 GHz, and the frequency of an output signal of the frequency multiplier is 244 GHz.

[0033] FIG. 7 provides a four-path in-phase terahertz transmitter of another structure. By taking an operating frequency of 244 GHz as an example, the transmitter comprises an oscillation source, a frequency multiplier, a power amplifier, and power dividers. A radio frequency signal transmitted by the oscillation source is doubled in frequency by the frequency multiplier, and then is input to the power divider after passing through one power amplifier to be divided into two; each of the two separate signals is divided into two again by another power divider. So far, one signal is divided into four paths of in-phase radio frequency signals, and the four paths of in-phase radio frequency signals are configured to directly feed all the N× end-fire linear array antennas respectively. In accordance with the embodiment, the frequency of the oscillation source is 122 GHz, and the frequencies of an output signal of the frequency multiplier, the power amplifier and the power divider are all 244 GHz.

[0034] Those skilled in the art may also improve the above transmitter structure such that the transmitter structure can transmit multiple paths of in-phase radio frequency signals at the same time to feed the linear type feed networks in all the N× end-fire linear array antennas respectively. The feed networks are connected to the M-path in-phase terahertz transmitter through matched 50-Ohm micro-strip lines or coplanar waveguides.

[0035] By connecting the linear type feed networks of M paths of N× end-fire linear array antennas to the M-path in-phase radio frequency signal transmitter and controlling the distance between two adjacent N× end-fire linear array antennas to be less than the effective wavelength, a higher gain and a higher half-power width can be realized, and the power consumption of transmitter can be reduced. Therefore, the array antenna is suitable for a millimeter wave and terahertz transmitter array system with high energy efficiency, high output power and low power consumption requirements.

[0036] The above are only specific embodiments of the present disclosure. Apparently, the present disclosure is not limited to the above embodiments, and may has many variations. All variations that those of ordinary skill in the art may directly derive from or associate with the contents disclosed in the present disclosure shall be considered as the scope of protection of the present disclosure.