The present invention discloses a novel six-port circuit.
A six-port circuit is a kind of circuit which is often used in, for example, wireless communication systems, particularly in the microwave range. A six-port circuit has two input ports and four output ports, and produces at each of its four output ports a signal which is a composite of the signals applied at the input ports, in which composite signal the phase difference between the input signals comprised in the composite signal differs between the output ports. Usually, the phase difference varies in “steps” of 90 degrees, so that at the four output ports, the following phase differences between the signals applied at the input ports at output ports can be accessed or obtained: 0 degrees, 90 degrees, 180 degrees and 270 degrees.
A conventional six-port circuit comprises a number of so called Wilkinson power splitters and 90 degree hybrid couplers, which leads to a large circuit which needs to be implemented as, for example, microstrip or strip line solutions on a substrate.
It is an object of the present invention to present a six-port circuit which obviates at least some of the disadvantages of previously known six-port circuits.
This object is achieved by the present invention in that it discloses a six-port circuit with first and second input ports and four output ports. The six-port circuit comprises a balun with its unbalanced end connected to the first input port for converting a first input signal at the first input port into first and second balanced input signals. The six-port circuit also comprises a filter which is a quadrature all-pass filter or a polyphase filter with first and second input ports and four output ports which constitute the four output ports of the six-port circuit.
In addition, the six-port circuit also comprises a power splitter connected to the second input port for splitting a second input signal at the second input port into a first and a second part of the second input signals. In the six-port circuit, the two input ports of the filter are connected so that one of the balanced input signals and one of the parts of the second input signals are connected to one of the filter's input ports, and the other of the balanced input signals and the other of the parts of the second input signals are connected to the other of the filter's input ports.
In one embodiment of the six-port circuit, the filter is a quadrature all-pass filter in which a first and a second of the filter's output ports are connected to each other by means of a resistor, as are a third and a fourth of the filter's output ports, and the first and fourth of the filter's output ports are connected to the filter's first and second input ports, respectively, by means of a first reactive component of a first kind, and the filter's first input port is connected to the filter's third output port by means of a first component of a second reactive kind, and the filter's second input port is connected to the filter's second output port by means of a second reactive component of the second kind.
In one embodiment of the six-port circuit with a quadrature all-pass filter, the reactive components of the first and second kind are chosen as either capacitors or inductors, so that the reactive components of the first and second kind are chosen as different kinds of reactive components.
In one embodiment of the six-port circuit, the filter is a polyphase filter which comprises four resistors and four reactive components of a first kind, where the resistors and reactive components of the first kind are connected in series to each other, serially “interleaved”, so that a resistor is connected serially to a reactive component of the first kind. In the polyphase filter, each of the four output ports is accessed at a point between a serially connected resistor and a reactive component of the first kinds. The serially connected components of the polyphase filter are serially connected in a “loop”, with the first input port of the polyphase being at a point between the “first” and the “last” component in the loop, and the second input port of the polyphase filter being at a point between the second component of the reactive component of the first kind and the third resistor.
The invention will be described in more detail in the following, with reference to the appended drawings, in which
a and 4b show a balun and a power splitter used in the invention, and
Embodiments of the present invention will be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the invention are shown. The invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Like numbers in the drawings refer to like elements throughout.
The terminology used in this text is for the purpose of describing particular embodiments only, and should not be used to limit the scope of the invention.
As is also shown in
In addition, the embodiment 100 also comprises a power splitter 120, which is connected to the second input port Vin2 of the six-port circuit 100, for splitting signals which are supplied to the second input port (“second input signals”) into a first 121 and second parts 122. The splitting is preferably equal, i.e. 50% of the input signal to each of the parts 121, 122, although other divisions are also possible.
The six-port circuit 100 also comprises a filter 105, which can be either a quadrature all-pass filter or a polyphase filter. Detailed examples of such filters will be given later in this text.
As shown in
The balanced ports of the balun 110 are connected so that one each of the first 112 and second 113 balanced input signals from the balun 110 is connected to one of the first, V′in1, and second, V′in2 input ports, of the filter 105.
The power splitter 120 splits the second input signal into two parts which have the same phase, while the balun 110 delivers two balanced output signals 112, 113 with a 180 degree phase difference between them. Due to this, and also due to how the balun 110 and the power splitter 120 are connected to the filter 105, as well as to the design of the filter 105, as a quadrature all pass filter or a polyphase filter, it will be possible to access output signals of the six-port circuit 100 at the four output ports Vout1-Vout4. The output signals at the four output ports Vout1-Vout4 will really be one composite signal with different phase: the composite signal will be a signal which is a composite of the signals which are input at the first and second input ports, and the phase difference between the signals which are input at the first and second input ports will differ between the four output ports, i.e. in the composite signal which can be accessed at those ports. The amplitudes of the signal at the different output ports may differ from each other.
Using the notations of
Turning now to the nature of the filter 105, an example of a first embodiment is given in
As is also shown in
Finally, as can also be seen in
Regarding the reactive components of the first and second kinds mentioned above and shown in
a shows an example of the balun 110 for use in the invention, and
The power splitter 120 shown in
Regarding the values of the inductors in
The outputs Vout1, Vout2, Vout3, Vout4 of the six-port circuit 200 will now be derived, in order to further explain the function of the circuit 100. In the example below, we will use an LO signal at amplitude VLO and frequency FLO as input to the balun 110, and an RF signal with amplitude VRF and frequency FRF as input to the power splitter 120. The reactive components 225, 230, of the first kind will be assumed to be capacitors with the magnitude C, and the reactive components 215, 220, of the second kind will be assumed to be inductors with the magnitude L. However, those skilled in the art will realize that the first kind of reactive component can equally well be coils, if the second kind of reactive component is chosen to be capacitances. The resistors 205, 210 are assumed to have the magnitude R. If there is only the RF signal as input to the circuit 200, i.e. at the power splitter 120, and we use VOUTiR to denote the output signal at output port i, where i=1, 2, 3, 4, we get:
V
OUT1R
=V
OUT2R
=V
OUT3R
=V
OUT4R
=V
RF (1)
where VRF is used to denote the signal which is one and the same at all of the four output ports.
Conversely, if there is only the LO signal as input to circuit 200, i.e. to the balun 110, and we use VoutiLO to denote the output signal at output port i, where i=1, 2, 3, 4, and where VLO is the input LO-signal, we get:
Also the composite signals Vout1 . . . Vout4, as shown in
where ω is an angle frequency which is common for both the RF and the LO signals.
Inserting (10) and (11) above into (6)-(9) above, we get:
V
out1
=V
RF+(1+j)·VLO (12)
V
out2
=V
RF+(−1+j)·VLO (13)
V
out3
=V
RF−(1+j)·VLO (14)
V
out4
=V
RF−(1+j)·VLO (15)
From equations (12)-(15), and writing VRF as VRF=IRF+jQRF, we obtain the square of the amplitudes of |Vout1|2, |Vout2|2, |Vout3|2, and |Vout4|2 as:
|Vout1|2=IRF2+QRF2+2IRF|VLO|+2QRF|VLO| (16)
|Vout2|2=IRF2+QRF2−2IRF|VLO|+2QRF|VLO| (17)
|Vout3|2=IRF2+QRF2−2IRF|VLO|−2QRF|VLO| (18)
|Vout4|2=IRF2+QRF2−2IRF|VLO|−2QRF|VLO| (19)
And, from equations (16)-(19), we obtain:
|Vout1|2−|Vout4|2=4|VLo|·(IRF+QRF) (20)
|Vout2|2−|Vout3|2=4|VL|·(−IRF+QRF) (21)
Thus, we can derive the I and Q components of the RF signal, IRF and QRF, from the differences of the square of the amplitudes, as follows:
It should be pointed out that the signals VRF and VLO used above signifies the “complete signal”, i.e. a signal which has both amplitude and phase.
As can be seen in
In addition, the serially connected resistors and reactive components of the polyphase filter 605 are connected in a “loop”: if we consider all of the serially connected resistors and reactive components in the filter 605, it can be seen that the “last” component, in this case the reactive component denoted as C4, is connected in series to the “first” component, in this case the resistor R1, thus forming a loop.
The first input port V′in1 of the polyphase filter 605 is at a point between the “first” and the “last” component in the loop, i.e. between the components denoted as R1 and C4 in
In the drawings and specification, there have been disclosed exemplary embodiments of the invention. However, many variations and modifications can be made to these embodiments without substantially departing from the principles of the present invention. Accordingly, although specific terms are employed, they are used in a generic and descriptive sense only and not for purposes of limitation.
The invention is not limited to the examples of embodiments described above and shown in the drawings, but may be freely varied within the scope of the appended claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2010/064113 | 9/24/2010 | WO | 00 | 3/22/2013 |