This application is a continuation of International Patent Application No. PCT/CN2008/070031, filed on Jan. 7, 2008, which claims priority to Chinese Patent Application No. 200710062806.3, filed on Jan. 18, 2007, both of which are incorporated by reference herein their entireties.
The present disclosure relates to the communication field and in particular to a directional coupler and a receiving or transmitting device.
Couplers are widely used in radio frequency and microwave systems to allocate and integrate signal power and to sample and detect power in a balance device of amplifier, phase shifter, filter, etc. A typical coupler is actually a four-port network dividing an input signal in a specific frequency range into two output signals the power of which is in a specific ratio. There are numerous types of couplers with different natures including a coupling line directional coupler arranged on a Printed Circuit Board (PCB).
A weak coupler (with a coupling degree of 30 dB) in the directional coupler is typically used to detect a level of a high-power signal between a Power Amplifier (PA) and an antenna feed system. “Directional” refers to the coupled signal is stronger at the second port than at the fourth port. If the coupling degree of the weak coupler is known, then the level of the input signal at the first port may be calculated simply by detecting the power level of the output signal at the second port. The fourth port is an isolation terminal where a useless signal is output and which is grounded via a match absorption load.
A highly directional (or high-directivity) weak coupler in a wireless access system is primarily used in power detection and standing wave detection circuits of an antenna feed system.
In order to implement high directivity of the weak coupler, it is generally required that the primary signal line and the coupled signal line be arranged in the same medium with an isotropic dielectric constant and magnetic leakage ratio.
If they are not arranged in the same medium, then there may be different phase velocities of odd and even modes (that is, an inappropriate ratio between mutual capacitance and mutual inductance), and in this case, manufacturers may adopt a modified structure to make the phrase phase velocities of the odd and even modes equal, thereby improving directivity. A directional coupler in the prior art is described briefly.
A first prior art relates to a metal rod coupler with the medium of air illustrated in
For the metal rod coupler with the medium of air, relative positions of the two metal rods subject to an assembling precision thereof may further influence a coupling degree and a directivity index of the coupler, so that the assembled coupler may suffer from poor consistency of the directivity index and thus has to be connected to an external adjusting element.
A second prior art relates to a hanging wire leap-line coupler shown in
There is another improved hanging wire leap-line coupler as illustrated in
Regardless of the hanging wire leap-line coupler in
A third prior art relates to a microstrip line directional coupler. A primary signal line and a coupled signal line of a conventional strip directional coupler are composed of strips, and the coupler is arranged in a non-uniform medium and thus has a poor directivity index. As illustrated in
A fourth prior art relates to an existing directional coupler illustrated in
Odd and even mode electromagnetic waves (simply referred to as odd and even modes hereinafter) are explained briefly here to facilitate better understanding of the disclosure later.
A phase velocity of either of the odd and even modes is dependent upon the nature of a medium in which the mode propagates. As well known, an electromagnetic wave propagates in the air at the velocity of light, and therefore both the phase velocity of the odd mode and that of the even mode are equal to the velocity of light.
Differently in the scenario of
The fast odd mode and the slow even mode may result in the poor directivity index of the coupler, and an increase in the phase velocity of the even mode may be impossible due to the structure of the coupler.
Summarily for above, the directional couplers in the prior art may not be satisfactory in terms of all the parameter indexes such as the directivity index, consistency of the directivity index, the PIM index, the power capacity index, etc., and one or more of the parameter indexes of the existing directional couplers have to be improved in the prior art with a demanding precision and a high cost. Consequently, the parameter indexes of the existing directional couplers may not be improved effectively at a low cost.
The embodiments of the present disclosure provide a directional coupler and a receiving or transmitting device to guarantee performance indexes of the directional coupler.
A directional coupler includes: a primary signal line composed of a metal rod; a coupled signal line composed of a micro strip; wherein the micro strip is in a curved shape and on a printed circuit board, and the medium between the metal rod and the micro strip is air.
A receiving or transmitting device in a radio frequency or microwave system includes a directional coupler including a primary signal line composed of a metal rod; a coupled signal line composed of a micro strip; wherein the micro strip is in a curved shape and on a printed circuit board, and the medium between the metal rod and the micro strip is air.
The embodiments of the present disclosure in comparison with existing directional couplers may have a low transmission loss, a large power capacity and a superior directivity index, guarantee a good PIM index, be assembled easily, have good consistency of indexes and be adapted to different application scenarios. The above directional coupler may guarantee various parameter indexes and be assembled easily at a low cost.
a illustrates a schematic diagram of a structure of a hanging wire leap-line coupler in the second prior art;
b illustrates a schematic diagram of a structure of an improved hanging wire leap-line coupler in the second prior art;
Various embodiments of the disclosure are described in detail below with reference to the drawings.
According to an embodiment of the present disclosure, the phrase velocities of the odd and even modes are substantially equal by decreasing the phrase velocity of the odd mode, thereby improving the directivity index of the coupler.
According to an embodiment of the present disclosure, the phase velocities of the odd and even modes are substantially equal by decreasing the phase velocity of the odd mode, thereby improving the directivity index of the coupler.
The phase velocities of the odd and even modes in the direction of the primary signal line may be made substantially equal by adjusting a geometrical size of the curve (e.g. a folded line or a smooth curve), thereby improving the directivity index of the coupler.
Particularly, the primary signal line (or referred to as a primary signal rod) 91 is composed of a metal rod arranged in the cavity, the air surrounds the metal rod, i.e. the primary signal rod 91, and the inner wall of the cavity is grounded (to provide electric shielding against interference radiation, etc.). As illustrated in
The coupled signal line is composed of a microstrip line 95 with a grounded reference plane (i.e. a backflow ground plane) 94. The coupled signal line made of the microstrip line results in easy assembling and guarantees a high pattern machining precision and assembling precision and good assembling consistency, thereby achieving good consistency of the parameter indexes.
The microstrip line in this embodiment is arranged in a curved status (e.g. in a shape like a curve of folded, smooth, zigzag, etc., but not limited thereto, and as well known, the coupled signal line curved at the 90 degree occupies the minimum area for the same length thereof), and the phase velocities of the odd and even modes may be made substantially equal by adjusting the pattern parameter of e.g. width, pitch, length, etc., of the folded or smooth curve, or stated in another way, a good directivity index may be achieved by making components of mutual capacitance and mutual inductance in an appropriate ratio.
In this embodiment, the metal rod and the microstrip line are arranged in parallel and non-coplanar planes and in parallel length-wise directions. The entire region (or each of segments) of the folded or smooth curve of the microstrip line is in an electromagnetic coupling relationship with the metal rod. In this embodiment, the primary signal rod is arranged at a position facing the right middle of the coupled signal line (the primary signal rod 91 is right above the coupled signal line 95 as illustrated in
In this embodiment, the microstrip line is kept in the same shape throughout the coupler for the minimum area, although the embodiment of the present disclosure is not limited thereto.
A window is arranged on the wall of the cavity of the primary signal line 91 in the direction corresponding to the coupled signal line 95 to function as a coupling path between the primary signal line and the coupled signal line. In
As can be seen from above, the primary signal line structured with a metal rod in the embodiment of the present disclosure may guarantee the ability of transmitting a high-power signal and a low insertion loss of the coupler as well as superiority of the PIM index due to the absence of a welding point. The coupled line of the coupler in the embodiment of the present disclosure is still made with a metal rod may guarantee the PIM index and the power capacity, and the use of the microstrip line on the PCB for the coupled line may ensure easy assembling and a high positional precision and hence good consistency of the indexes. The printed circuit technologies have been rather mature at present, and a pattern precision may normally be up to 0.03 mm far above an assembling error. Therefore, the high precision of a PCB pattern may avoid the accumulative assembling error in welding and assembling the coupled rod in the first and second prior art, thereby guaranteeing good consistency of the indexes.
In this embodiment, the arrangement of the microstrip line in a curved status may make the phase velocities of the odd and even modes consistent, thereby improving the directivity index of the coupler. An additional advantage of the coupler may lie in that the directional couplers in the prior art are generally of a narrowed and elongated type, while the curved arrangement of the microstrip line in the embodiment of the present disclosure may shorten the length of the coupler and thus facilitate deployment in a microwave device (for a reduction in an occupied area, for example) especially on a PCB. Generally, in the case that an electric length is equal to a quarter of the wavelength, a coupling degree may vary inconspicuously as the frequency varies, while in the case that the electric length is below or above a quarter of the wavelength, the coupling degree may vary conspicuously as the frequency varies so that the coupling degree at a slope may fluctuate in a non-flat way. Therefore, the coupler with an electric length equal to a quarter of the wavelength is referred to as a narrowband coupler. The coupled line in the embodiment of the present disclosure may be made with an electric length equal to a quarter of the wavelength. The electric length equal a quarter of the wavelength may be realized in a region of a relatively short physical length (e.g. one tenth of the wavelength), where the physical length is equivalent to the length of the metal rod and the electric length is equivalent to the total length of the folded microstrip line. When the electric length of the coupled line is a quarter of the wavelength, the coupling degree varies slightly as the frequency varies so that the coupling degree may be made flat in a relatively small coupling region even at a relatively low frequency.
The parameter indexes in this embodiment each are provided with a margin, and therefore there is a considerable degree of freedom available to accommodate different application scenarios. The directivity index among tested indexes of an existing product board may be up to 30 dB and even maximum 50 dB far above a general index required for a product (28 dB).
The above directional coupler may be arranged in a receiving or transmitting device of a radio frequency or microwave system for use in power detection and standing wave detection circuits of an antenna feed system.
The embodiment of the present disclosure improves the three-dimension structure of the existing high-directivity directional high-power weak coupler so that the improved coupler with a good directivity index, good consistency of the index, a good PIM index, a large power capacity and a low transmission loss may be made with a simple structure, at a low cost and with easy assembling.
The above embodiments are provided merely to illustrate but not limit the disclosure. Any modifications, alternatives and adaptation made without departing from the principle of the disclosure shall fall into the scope of the claims appended to the disclosure.
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2007 1 0062806 | Jan 2007 | CN | national |
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Number | Date | Country | |
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20090278623 A1 | Nov 2009 | US |
Number | Date | Country | |
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Parent | PCT/CN2008/070031 | Jan 2008 | US |
Child | 12505739 | US |