EP2043193B1

EP2043193B1 - A directional coupler and a method thereof

Info

Publication number: EP2043193B1
Application number: EP07291176.1A
Authority: EP
Inventors: Poul Jeppesen; Alexander Riisberg
Original assignee: Alcatel Lucent SAS
Current assignee: Alcatel Lucent SAS
Priority date: 2007-09-28
Filing date: 2007-09-28
Publication date: 2013-04-24
Anticipated expiration: 2027-09-28
Also published as: EP2043193A1

Description

Technical field

The invention relates to the field of microwave communication, and more particularly without limitation to a directional coupler in radio frequency power transmissions and a method of producing a directional coupler.

Background and related art

Impedance matching is a critical term in order to understand the performance of a power transmission between source and load in any arbitrary system. The voltage standing wave ratio (VSWR) is a scalar measurement that reveals how well the load impedance is matched to the source.
Directional couplers are used for sampling the power transmission with a minimum disturbance of the transmitted signal. These are passive devices configured as four-port circuits. Two of the ports are used for power input and transmission, while the remaining two receive a coupled fraction of the transmitted power as well as being used for isolation purposes.
When a wave is present along the transmission line, a percentage of the wave is reflected while the rest of the signal passes through. This percentage is known as the reflection coefficient. Depending on the position of the coupling and the isolating port within the directional coupler and whether or not it's terminated farthest from or closest to the input from the outside connection, the coupled signal will correspond to the forward or the reverse wave. There are some important definitions related to directional couplers, the most important are: coupling factor, isolation and directivity. Let the input port be P1, transmitted port P2, coupled port P3 and isolated port P4, then the definitions may be expressed as: $Coupling Factor (CF) = 10 * \log (P 1 / P 4)$
$Isolation (l) = 10 * \log (P 1 * P 3)$
$Directivity (D) = Isolation (l) - Coupling Factor (CF)$
Using a forward and a reverse directional coupler, the voltage standing wave ratio (VSWR) may be calculated when the forward and the reverse waves are added to form a composite signal, the maximum and minimum voltage is measured and the ratio of the maximum and the minimum is calculated.
WO 2007/099202 A1 discloses a directional coupler comprising three ports, a transmission path with a conductor, a signal ground and the interspace to lead a signal to be measured from the ports and a first sensing conductor located in the interspace parallel to the transmission conductor. In the interspace of the transmission path there is a second sensing conductor parallel to the transmission conductor, both the first and the second sensing conductor have ends connected to each other to the measurement port by a measurement conductor. Both sensing conductors also have the form of a strip conductor.
One of the shortcomings regarding VSWR measurements is the low directivity values of the directional couplers, the instability of the coupling factor and long tuning times. In prior art, the values of the directional coupler fluctuate more often and a more frequent tuning of attenuation network (e.g. a potentiometer) around the coupler is required in order to balance the Coupling Factor back in place. There is, therefore, a need to improve the directivity values without further disturbing the transmission power. There is a further need to improve the stability of the measurements to obtain a more precise value of the directivity (and thereby any VSWR detection) and, as a consequence, a reduction of the tuning time.

Summary of the invention

The present invention provides a directional coupler according to claim 1.
The directional coupler has the advantage that the filling element keeps the predefined distances between the first and the third conductor, as well as between the second and the third conductor. This maintains stable coupling factors and directivity values, reducing tuning time, and avoiding fluctuation in the measured signal.
Another advantage by stabilizing the directional coupler is that, as there is an element that fixes the third conductor within the cavity, the coupler is easier to reproduce as the directivity values are set up by the distances between the conductors.
Another advantage is that the amount of defective directional couplers is diminished and the amount of repair loops is reduced, bringing an overall decrease of production time and costs. An even further advantage is that the consistency of the coupling and the isolation levels increases the directivity values compared to prior art. According to the inventors, the directional coupler reaches directivity values up to 38 dB, whereas the prior art reaches only a maximum of 30 dB. Surprisingly, the filling element in the interior of the cavity has not shown greater disadvantage in terms of coupling factor and directivity values, compared with directional couplers with no filling element. The non-conductive material has the advantage of minimizing power radio frequency transmission interference.
The filling element is made of milled Teflon (PTFE), or molded Polyethylene or Fluorinated Ethylene Propylene (FEP). These filling elements have shown the best directivity and coupling values among all the non-conductive materials analyzed. However, the filling element could be made of any material with non-conductive properties.
In another preferred embodiment the insulator is air. One of the advantages of using air as an insulator when measuring the transmission power is that the coupling factor levels can reach high levels, as the parallel portion of third conductor can be arbitrarily close to the first conductor.
In another embodiment, the end portions of the third conductor of the directional coupler are connected and integrated to a printed circuit board that also includes a low noise amplifier (LNA). This type of connection has the advantage of reducing the insertion loss and material costs by keeping the connections between the devices close to each other.
In another aspect, the invention relates to a voltage standing-wave ratio measurement system that includes a coaxial cable, a first and a second directional coupler as described in the preferred embodiment, arranged at separate distance of the coaxial cable, and at the same time, allowing the processing of the forward and reverse RF power transmission in order to calculate the VSWR.
In a preferred embodiment, the distance between the third and the first conductor, as well as the distances between a third conductor and the second conductor define the directivity values of the directional coupler.
In another embodiment, the invention relates to a coaxial cable that includes a directional coupler as mentioned above. The advantage of using a directional coupler within a coaxial cable is that the coupler is in a close distance to the first and the second conductor, and therefore better coupled to the transmitted signal.
In another aspect, the invention relates to a method of producing a directional coupler that includes providing a coaxial cable that has a first conductor, an insulator surrounding the first conductor and having an outer surface, and a second conductor surrounding the insulator. Then, a cavity in the second conductor is formed, extending to at least the outer surface of the insulator. Subsequently, in the interior of the cavity a third conductor is placed, having a portion that is substantially parallel to the first conductor and the end portions or the extremes substantially perpendicular to the first cond uctor. After that, at least a portion of the cavity is then filled with a filling element made of a non-conductive material, holding permanently the third conductor.
In a further embodiment, the invention relates to a method of producing a directional coupler as mentioned in previous embodiments with a filling element made of milled Teflon (PTFE), or molded Polyethylene or Fluorinated Ethylene Propylene (FEP).
In a further embodiment, the invention relates to a method of producing a directional coupler as mentioned in previous embodiments wherein the insulator is air

Brief description of the drawings

In the following preferred embodiments of the invention are described in greater detail by way of example only making reference to the drawings in which:

Fig. 1: is a schematic of a longitudinal cut of the directional coupler,
Fig. 2: is a schematic of a 3-D view of the directional coupler,
Fig. 3: is a representation of a transversal cut of the directional coupler.

Detailed description

Fig. 1 shows a longitudinal cut of the directional coupler 100, allowing a detailed description of the inner elements that structure it. The first conductor 101 is surrounded by an insulator 102. The insulator 102 is surrounded by a second conductor 103; these two conductors allow a power radio frequency transmission. On the top of second conductor 103, printed circuit board (PCB) 109 is located. In the second conductor 103, there is a cavity 104 that it extends from printed circuit board 109 to the interface with the insulator 102. Inside this cavity 104, there is located a third conductor 105 made of a non-conductive material; this third conductor 105 is formed by a portion that is substantially parallel to the first conductor and with both ends substantially perpendicular to the first conductor 101. In the cavity 104, a filling element 106 fills at least a portion of the cavity 104.
When a signal is transmitted through first conductor 101 and second conductor 103 a fraction of the signal is received by third conductor 105. The third conductor 105 allows a coupling of the transmitted radio frequency power. This sample signal can be measured through the output port 107 of the third conductor 105, while the isolated port 108 may be connected to a 50 Ohm termination. The filling element 106 fills at least a portion of the cavity 104, holding all the portions of third conductor 105 and keeping the distances between third conductor 105 and first conductor 110, and between third conductor 105 and second conductor 111.
One of the advantages of the invention is that there is no need of adjusting the mounting height of the third conductor to obtain the designed coupling factor using for example locking screw; there is also no need of turning or rotating the third conductor in order to obtain the desired directivity; there is also no need of iterative measurements and adjustments of either the coupling factor or the directivity after the position of the third conductor has been changed. In all this cases, the filling element keeps the right distances and designed values obtained during the development phase of the product.
The filling element 106 can be made for example from a non-conductive material. This non-conductive material can be for example milled Teflon and Polyethylene. In one example, the insulator 102 is air. In another example the output ports 107 and 108 and the third conductor 105 is integrated or connected to a printed circuit board 109.
One of the most important advantages of the filling element 106 is that the positions between the first and the third conductor 110 and the distance between second and third conductor 111 can be fixed permanently. This ensures stable measurement and reduced adjustment of the directivity and coupling values.
Fig. 2 illustrates a three-dimensional view of the directional coupler, where the form of the conductors is represented. The figure 2 shows the insulator 102 surrounding first conductor 101, and second conductor 103 surrounding the insulator 102. The figure 2 also depicts the cylindrical shape of the first 101, second 103 and third conductors 105. Also, the cavity 104 with a substantially rectangular shape within second conductor is shown. In the interior of cavity 104, the parallel portion and the perpendicular ends of third conductor in respect to the first conductor is illustrated. The filling element 106 fills the section of the cavity 104 between the parallel portion and the perpendicular ends of third conductor 105.
Fig. 3 illustrates a transversal cut of the directional coupler, representing the cavity 104 location within the second conductor 103, having a rectangular shape and starting on the interface with the printed circuit board (PCB) and ending at least in the interface with the insulator 102. The insulator 102 surrounds the first conductor 101 and the second conductor 103 surrounding the insulator 102. On the top of second conductor 103, the printed circuit board (PCB) 109 is located. The cavity 104 starts at the printed circuit board 109 reaching the outer surface of the insulator 102. The third conductor 105 is located in a substantially central position within the cavity 104. The filling element 106 fills the section of the cavity 104 between the parallel portion and third conductor 105 and the interface with the printed circuit board (PCB) 109. Fig. 3 also shows the filling element 106 keeping the distance between the third conductor and the first conductor 105 and the distance between third conductor and second conductor 111.

List of Reference Numerals

100	Directional coupler
101	First conductor
102	Insulator
103	Second conductor
104	Cavity
105	Third conductor
106	Filling Element
107	Coupled port
108	Isolated port
109	Printed Circuit Board (PCB)
110	Distance between third and first conductor
111	Distance between third and second conductor

Claims

A directional coupler (100), comprising:
a first conductor (101);

an insulator (102) surrounding said first conductor (101) having an outer surface; a second conductor (103) surrounding said insulator (102), the first and the second conductor being adapted for power RF (radio-frequency) transmission;

a cavity (104) in said second conductor (103) extending to at least the outer surface of the insulator (102);

a third conductor (105) in the interior of said cavity (104) having a portion parallel to the first conductor and end portions perpendicular to the first conductor (101), the third conductor (103) being arranged for receiving a portion of said power RF transmission; and a filling element (106) made of a non-conductive material, for filling completely the cavity, permanently holding the third conductor (105),

wherein the filling element (106) consists of milled Teflon (PTFE), or molded Polyethylene or Fluorinated Ethylene Propylene (FEP), wherein said end portions of said third conductor (105) are adapted to be connected to a printed circuit board (109).
A directional coupler (100) as claimed in claim 1, wherein the insulator (102) is air.
A method of producing a directional coupler (100), comprising the steps of:
- providing a coaxial cable, having a first conductor (101), an insulator (102) surrounding said first conductor (101) having an outer surface and a second conductor (103) surrounding said insulator (102);

- forming a cavity (104) in said second conductor (103) extending to at least the outer surface of the insulator (102);

- placing a third conductor (105) in the interior of said cavity (104) having a portion parallel to the first conductor (101) and end portions perpendicular to said first conductor (101);

- filling completely said cavity (104) with a filling element for permanently holding the third conductor (105), said filling element being made of a non-conductive material, wherein the filling element (106) consists of milled Teflon (PTFE), or molded Polyethylene or Fluorinated Ethylene Propylene (FEP), wherein said end portions of said third conductor (105) are adapted to be connected to a printed circuit board (109).
A method of producing a directional coupler (100) as claimed in claim 3, wherein the insulator (102) is air.