NO128636B - - Google Patents

Description

Phase comparator.

The present invention relates to phase comparators and has as

purpose of providing improved and relatively simple

phase comparators which are of such a nature that a signal is produced at one output terminal which is here referred to as an "ambiguous" output signal and which is derived from the phase relationship between two radio frequency (R.F.) signals supplied to the comparator, and at another output terminal a signal which here is referred to as an "unequivocal" output signal, and which is also derived from the phase relation. between the said two R.F. signals. The meaning of the two mentioned expressions "ambiguous" and "unequivocal" can be understood from the following description.

A "unique" phase comparator outputs a common voltage equal to zero when two R.F. signals applied to the comparator are in phase and of the same magnitude and of maximum value when there is a 180° phase difference between two R.F. signals of the same magnitude. The sign of the direct voltage is independent of the sign of the phase difference, i.e. whether this is positive or negative. The term "unique" is usually used for this type of comparator because there is no unambiguous phase indication when the output DC voltage is equal to zero.

In the "ambiguous" type of comparator, as it is commonly known and used, the comparator itself receives three R.F. input signals, two of which are derived from the first of the R.F. sources to be compared, and the other is derived from the second of these sources. The first R.F. source, which to facilitate the present explanation may be assumed to be a reference source with a fixed phase, is used to provide two input signals with a fixed phase for the comparator, one signal having a phase of 0° and the other a phase of 180° . When the two RF sources are in phase, the RF signal from the second source (which provides the third RF input signal to the comparator) is 90° out of phase with respect to the 0° phase signal derived from the first source. The three RF input signals are grouped into two pairs of phases 90°, 0° and 90°' 180°, and it will be obvious that the vector sum of each pair will depend on the phase shift of the second RF source relative to the first. The comparator rectifies the vector sum but for each pair to form DC voltages of opposite polarity,

one positive and the other negative, whereupon these voltages of opposite polarity are added algebraically to produce a resultant voltage which is 0° when the two R.F. sources are in phase or are in a 180° phase shift. This resulting voltage is of one polarity if the phase relationship between said two sources is between 0 and 180° and of the opposite polarity if said phase relationship is between 180 and 0°. The term "ambiguous" is used for this comparator type because a resulting DC voltage equal to 0 appears both when the two R.F. sources have a phase relationship of 0° and of 180°.

There are many devices, particularly those which use DC output signals from a phase comparator to effect automatic phase correction, which require both unambiguous and unambiguous phase comparison between two R.F. sources. If two phase comparators, one ambiguous and the other unambiguous, are used according to common practice, the resulting arrangement becomes disproportionately complicated, because it is normally necessary to derive five R.F. output signals from the two sources whose phase is to be compared, namely two for the unambiguous comparator and three for the ambiguous one.

The object of the present invention is to provide improved phase comparators which only require two R.F. input signals from the two sources whose phase is to be compared, and which have two output terminals, one of which outputs the result of an ambiguous phase comparison and the other the result of an unambiguous phase comparison.

The invention is thus based on a phase comparator designed to carry out both ambiguous and unambiguous phase comparators between two input signals and to make the results of the comparison available at each of two output terminals. On this background, the comparator according to the invention has as a distinctive feature that it comprises four four-port quarter-wave directional couplers, two of which are designated as input couplers and two are designated as output couplers, as each coupler is equipped with two diagonally opposite input ports and two diagonally opposite output ports; interconnections arranged for interconnecting the four couplers in a ring coupler, in such a way that output ports for said input couplers, within the ring coupler, are connected to input ports for the output couplers; a 90° phase shifter interposed in one of said interconnections; a first input device for supplying one of said input signals to an input port for one of the input couplers; a second input device for supplying the second input signal to an input for the second input coupler, which lies above the two output couplers separated from said one input coupler a first rectifier device for rectification of . the vector sum of the two resultant signals occurring at an

.output port for one of said two output couplers, for'o

producing a unique output signal; another rectifier device for rectifying the vector sum of the two resulting signals appearing on one output port of the other output coupler to produce a DC voltage of a specific polarity; a third rectifier device for rectifying the vector sum of the two resulting signals appearing on the second output port of said second output coupler to thereby produce a DC voltage of opposite polarity; as well as a summing device for algebraically summing the two DC voltages to produce an ambiguous output signal.

Preferably, the directional couplers are 3dB quarter-wave directional couplers of the line type, and the remaining ports of the couplers are suitably connected to their respective termination impedances, which are equal to

characteristic impedance of the connected connector.

The invention will be further explained in connection with

attached drawings, in which fig. 1 schematically shows the preferred embodiment of the invention, and fig. 2-6 are explanatory

diagrams and graphic figures.

Reference must now be made to fig. 1 where a phase comparator is shown

with four quarter-wave 3^B directional couplers, three detectors, a direct voltage summing circuit and a 90° phase shifter, which in this embodiment is made up of a quarter-wave line. The couplers are designated 1C, 2C, 3C and hC, and each has four ports indicated by the designations iCp 1C2, 1, 10^; 2C1 -2C2, 2C^, 20^;

3C1 , 3<C>2, 30^, 30^; and 1fC1 , i+C2 , hCy hC^ . The detectors have the reference designations 1D, 2D, 3D; the summation circuit is designated S, and the quarter-wave line is designated QL. The two R.F. entrance

signals to be compared are fed to the comparator. One of these, which will be designated as input signal A, is fed to terminal A and the other, which will be designated as input signal B,

a clamp B is supplied. In fig. 1, and also in the explanatory figures 2 and 5, certain phase designations are indicated near the ports of the couplers where they appear. The indicated phases have an index A when they relate to input A and an index B when they relate to input B. These indicated phase phase designations are everywhere those that appear: when the two R.F.

signals A and B are in phase.

For further description of fig. 1, reference should be made to the explanatory fig. 2-6, where fig. 2 shows an ambiguous comparator, and the curves in fig. 3 and k- concern this. Fig. 5 shows an unambiguous comparator, and the curve in fig. 6 concerns this. In fig. 2, an input signal A with 0° phase is supplied to port C. for a quarter-wave 3dB directional coupler C, and the phase of this signal at port C2 will be the same, so that 0°A will be present at both of these ports. At port C, the A signal will be out of phase by 90°

and 90 o^ will perform here. If ports C o and C are terminated with the characteristic impedance of the coupler, the A signal will produce no signal at port C^.

The B signal is applied to port C^. Since it is assumed that the A and B signals

is in phase, the B signal at port C^ will have a phase relationship of 180°

relative to the A signal at gate . This is indicated by the inscription 180°B near gate C^. The B input signal at gate will produce signals at gates C and C~ with phases of 180° and 270° respectively, as indicated. Detector 1D rectifies the vector sum of the two signals at port G^, while detector 2D rectifies the vector sum of the two signals at port C-^, so that the two detectors produce DC voltages with opposite polarities. These two voltages are then added algebraically in the summing circuit S,

and thereby produces at AM an ambiguous phase comparison output signal, which, when the signals A and B are in phase and of the same magnitude, will be equal to 0. The detectors 1D and 2D have impedances equal to the characteristic impedance of the coupler, so that no reflection signals appear at gates C2 and C^.

The upper and lower curve in fig. 3 shows, respectively, the direct voltage output signal V from detectors 1D and 2D when the phase of the B signal at terminal B is varied in relation to the phase of the A signal at terminal A, while the curve in fig. h is the corresponding curve for the voltage at the output terminal AM. As will be seen, this curve passes through 0 when the input signals A and B

are either in phase or have a mutual phase relationship of 180°.

In the unambiguous compare in fig. 5, the A signal is added

port C, for quarter-wave 3dB directional coupler C and B signal becomes

access port C^. Port C is terminated in the characteristic impedance of the coupler, which is conventionally shown by TR. Assuming that the input signals A and B are in phase, the B signal at port will have a phase relationship of 90° in relation to the A signal at port , as indicated by the inscription 90°B near port C^. The A input signal will produce 0°^ at port C2 and 90°A at port , while the B input signal will produce 180°B at port Cp and 90° at port CL , as indicated. The vector sum of the two

B 3

signals at port C2 are detected by detector 3^ as 1D and 2D

in fig. 2, em has an impedance equal to the characteristic impedance of the connector in question, whereby an unambiguous phase comparison signal appears on the output terminal NAM. Fig. 6 graphically shows the variation of the output voltage V at terminal NAM when the phase relationship between the A and B input signals is varied. As will be seen, the voltage V drops to 0 only when the input signals are in phase.

Reference must now be made again to fig. 1 where the A signal over clamp

A is supplied to port 1 CL of coupler 1C and produces 0°A VQ(^

ports 1C1 and 1C2 and 90°A at port 1C^. Port 1 is terminated in the characteristic impedance of the coupler 1C as indicated by 1 TR.

The B signal at terminal B is fed to port 3C^ for connector 3C, and provides 180°B at ports 3^ and 3C2 as well as 270°B at port 3C for the respective connector. Port 30^ is terminated in the characteristic impedance of the coupler, as indicated by -3 TR.

Port 1C2 of connector 1C is connected to port 2C^ of a further connector 2C, and port 3C2 of connector 3C is connected to port 2C^ of connector 2C. Consequently, in coupler 2C the phase 0°A will occur at 2C| , the phases 0°A and 270°B will occur at 2C2, the phases 90°A Qg 180°B will occur at 2C^, and the phase 180°B will occur at 2C^. The vector sum of the two signals at 2C2 is detected by the detector 1D and the vector sum of the two signals at 2C^ is detected by the detector 2D. These detectors are arranged to produce DC voltages of opposite polarities, and each has an impedance equal to the characteristic impedance of the coupler 2C. The two DC voltages are added algebraically in the summation circuit S, and an ambiguous phase comparison signal appears on the output terminal AM.

Port 3C3 of the coupler 3^ is connected through a quarter-wave line QL or other suitable 90° phase shifter to port hC^ of the fourth coupler, whose port ^-C^ is terminated in the characteristic impedance of said" coupler as indicated by •+ TR. The ports hC^ for coupler Mn and 1 for coupler 1C are interconnected. Consequently, in coupler kC the phase 360°B (<=0>°B) will occur at port <i>+C-, the phases 0°B and 180°A will occur at port hC^, the phases 90°A and 9<0> B

will appear at port ^C^ and the phase 90°A will appear at port ^C^. The vector sum of the two signals at port hC^ for coupler hC is detected by detector >+D, which has an impedance adapted to the characteristic impedance of the coupler in question and which provides an unambiguous output signal at terminal NAM.

When comparing fig. 1 with fig. 2 and 5 it will appear that

in fig. 1 the addition of two quarter-wave 3dB directional couplers and a 90° phase shifter produces an arrangement that actually

incorporates both an ambiguous and an unambiguous phase comparator and which can be driven by the two R.F. sources whose phases are to be compared.

As shown, the couplers are preferably of the so-called line type, but any electrically equivalent couplers can of course be used.

Claims (3)

1. Phase comparator arranged to perform both ambiguous and unambiguous phase comparison between two input signals and to make the results of the comparison available at each of two output ports, characterized in that it comprises four four-port quarter-wave directional couplers, two of which are designated as input couplers (1C ,3C) and two are designated as output connectors (20,^-0), as each connector is equipped with two diagonally opposite input ports and two diagonally opposite output ports; interconnections arranged for interconnection of the four couplers in a ring connection in such a way that output ports for said input couplers, within the ring connection, are connected to input ports for the output couplers; a 90° phase shifter (QL) which is damaged in one of said interconnections; a first input device (A) for supplying one of said input signals to an input port (ICI) for one (1C) of the input couplers; another input device (B) for supplying the second input signal to an input (3CT) for the "second input coupler (3C), which, above the two output couplers (2C, hC) is located separately from said one input coupler (1C); a first rectifier device (3D) for rectifying the vector sum of the two resulting signals appearing at an output port ( hC2 ) of one of said two output couplers ( hC ), to produce an unambiguous output signal;-another rectifier device (ID) for rectifying the vector sum of the two resulting signals acting on one (2C2) output port of the other output coupler (2C), to produce a DC voltage of a certain polarity; a third rectifier device (2D) for rectifying the vector sum of the two resulting signals appearing on the other output port (2C3) of said other output coupler to thereby produce a DC voltage of opposite polarity, as well as a summing device (S) for algebraically summing the two DC voltages for to produce an ambiguous output signal. 2. Compares as stated in claim 1, characterized in that the directional couplers are 3dB quarter-wave directional couplers (1C, 2C, 3c, hC) of the line type. 3. Compares as stated in claim 1 or 2, characterized in that the other ports of the directional coupler (lCh, 3C^,*+C3) are each connected by a summing impedance, which is equal to the characteristic impedance of the connected coupler.