Hybrid coupler with sum and difference ports located on the same side

Abstract

This invention refers to hybrid coupler with the sum port and difference port located on the same side. The hybrid coupler can be efficiently integrated into the high frequency circuit with its simple structure, using common material. To achieve this purpose, the hybrid coupler in this invention consists of the following parts: sum port, difference port, output port 1, output port 2, connection line 1, connection line 2 and microstrip line.

Claims

1. A hybrid coupler with the sum port and difference ports located on the same side of the straight-line that connects the two outputs, the hybrid coupler comprises: a sum port, a difference port, a first output port, a second output, a first connection line, a second connection line and microstrip lines: The sum port and difference port have flat structure and are made of copper The first output port and second output port have flat structure and are made of copper The first connection line, second connection line and microstrip line are made of copper.

2. A hybrid coupler with sum port and difference ports located on the same side of the straight-line that connects the two outputs, said hybrid coupler having microstrip lines, a slot-line, and a substrate with top and bottom copper layers, wherein: the microstrip line dimensions are designed based on a microstrip line calculation principle, the slot-line dimensions are designed based on a calculation principle of coplanar waveguide and the material of dielectric layer, wherein dielectric constant is 2.64, a dielectric layer thickness is 1.542 mm; top and bottom copper layers are 0.035 mm.

3. A hybrid coupler with a sum port and a difference port located on the same side: a signal from the sum port is transmitted to a microstrip line, then transformed to an odd mode signal that is transmitted on a slot-line via a first connection line, an odd mode signal is transformed to the microstrip line via a second connection line and transmitted to a set of output ports; the slot-line, first and second connection lines, the output ports are designed so that the output ports are symmetrically located to the slot-line structure; wherein, due to the symmetry of the 2 output ports and odd mode characteristics, the output signals of two output ports have balanced amplitudes and phases; wherein signal from the difference port is transmitted to the microstrip line, is then transformed to the even mode signal that is transmitted on the slot-line.

4. The hybrid coupler according to claim 3, wherein even mode signal is then transformed to the microstrip line via the connection line 2 and is transmitted to two of the set of output ports.

5. The hybrid coupler according to claim 4, wherein due to the symmetry of the 2 output ports and the even mode characteristic, output signals of the two output ports have the equal amplitudes but 180 degree phase-shifted; wherein to achieve the even mode signal on slot-line, the length of the microstrip line connected to the difference port must be lambda/4, where lambda is a center frequency wavelength.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0006] FIG. 1: Top layer of the hybrid coupler;

[0007] FIG. 2: Bottom layer of hybrid coupler;

[0008] FIG. 3: Connection lines position;

[0009] FIG. 4: Relative position of top and bottom layer; and

[0010] FIG. 5: Even and odd mode

DESCRIPTION OF INVENTION

[0011] The hybrid coupler in this invention includes: Sum port (1), difference port (2), output port 1 (3), output port 2 (4), connection line 1 (5), connection line 2 (6) and the microstrip line (7)

[0012] Referring to FIG. 1, FIG. 2 and FIG. 3, sum port (1) and difference port (2) have the copper microstrip structure. To locate the sum port (1) and difference port (2) on the same side, signal from the sum port and difference port are transmitted to output port 1 (3) and output port 2 (4) (which also made by copper and have microstrip structure) via the microstrip line (7), connection line 1 (5), connection line 2 (6) (refer to FIG. 3) and slot-line structure in the bottom layer (refer to FIG. 2).

[0013] Referring to FIG. 4 and FIG. 5, signal from the sum port (1) is transmitted to microstrip line (7), then transformed to the odd mode signal that transmitted on 2 slot-line via the connection line 1 (5). The odd mode signal is then transformed to the microstrip line via the connection line 2 (6) and transmitted to output port 1 (3) and output port 2 (4). The slot-line, connection line 1 (5), connection line 2 (6), output port 1 (3) and output port (4) are designed so that the output port 1 (3) and output port 2 (4) are symmetrically located to the slot structure. Due to the symmetry of the 2 output port (3), (4) and the odd mode characteristic, the output signals of output port 1 (3) and output port 2 (4) have the balanced amplitudes and phases.

[0014] Referring to FIG. 4 and FIG. 5, signal from the difference port (2) transmitted to microstrip line (7), transformed to the even mode signal that is transmitted on slot-line. The odd mode signal is transformed to the microstrip line via the connection line 2 (6) and transmitted to output port 1 (3) and output port 2 (4). Due to the symmetry of the 2 output ports (3), (4) and the even mode characteristic, the output signals of output port 1 (3) and output port 2 (4) have balanced amplitudes but are 180 phase-shifted. To achieve the even mode signal on the slot-line, the length of the microstrip line connected to difference port (2) must be lambda/4 (lambda is the center frequency wavelength).

[0015] The microstrip line dimensions are designed based on the microstrip line calculation principle, the slot-line dimensions are designed based on the calculation principle of coplanar waveguide and the material characteristic of dielectric layer (dielectric constant, dielectric layer thickness) to meet the operating frequency requirement and the impedance requirement of the (1), (2), (3) and (4) ports (the impedance of ports in this invention is 50 Ohm). The dielectric layer characteristics in this invention: dielectric constant is 2.64, dielectric layer thickness is 1.542 mm, top and bottom copper layers thickness is 0.035 mm.

[0016] The sum port (1) and difference port (2) are arranged on the same side and symmetrically to the slot-line. The lengths of microstrip lines (7) connected to sum port (1) and difference port (2) are calculated and designed so the phases of received signal from port 1 (3) to the sum port (1) and difference port (2) are in-phase.

[0017] Because the even mode and odd mode have the 180 phase-shifted characteristic so the signal from sum port (1) will almost be canceled at the difference port and vice versa, thereby the isolation between sum and difference ports is perfect.

[0018] In conclusion, this invention introduces a hybrid coupler with sum port and difference port located on the same side, the fabrication of hybrid coupler to the system becomes much simpler. The invention presents the hybrid coupler taking advantages of 2 layer printed circuit technology, using common material to meet the hybrid coupler's technical requirements.