Patent Publication Number: US-4056792-A

Title: Wideband diode switched microwave phase shifter network

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to diode switched circuits for providing an adjustable phase shift network, of the type constructed by miniaturized circuits utilizing microstrip delay line structures and with phase increment adjustments performed by the switching of diode &#34;chips&#34; mounted to the delay line structure in a manner of high density packaging. More particularly, the invention relates to an improved electrical design of such a network. 
     2. Description of the Prior Art 
     In diode switched phase shifters, of the type referred to, changes in phase shift are accomplished by altering the D.C. current distribution to the diodes in the network. These diodes present either short circuits or open circuits to the R.F. energy, depending upon whether they are conducting or non-conducting. In the prior art, the diodes are from a D.C. standpoint, individual diodes and controlled by individual driver circuits which provide their forward bias. Another known practice, where the functions of several diodes are identical, is for such several diodes to be biased from the same driver source, with the diodes connected in parallel relative to this source. A typical configuration of the driver has the D.C. forward bias voltage applied across the diode or diodes through a collector-emitter path of a transistor switch. An individual network of voltage source and transistor switch is applied to each diode or each of several diodes having the same function. 
     In applications where source power is at a premium such as in satellites, or where power dissipation can cause severe thermal problems such as in compact airborne radars, these prior art approaches dissipate relatively high amounts of power. This is because a minimum of 5 volts for the diode forward bias source is desirable for reasons of regulation and power supply efficiency. The required diode current is a function of the diodes, and the total average power required in a network will be: 
     
         P = N · I · V 
    
     where: 
     I = required diode current; 
     N = average number of diodes conducting; and 
     V = source voltage. 
     In a typical case the diode current would be 100 ma. For a 10 diode circuit the power source requirement would be 5 watts. Accordingly, there has been a continuing effort to obtain reductions in the power consumption required for operation of a diode switched phase shifter networks. 
     In addition to the above discussed needs for achieving lower power dissipation in such phase shifter networks, there is a continuing need for providing such networks which have wider bandpass characteristics, and lower R.F. insertion losses. 
     SUMMARY OF THE INVENTION 
     A diode switched phase shifter network of the type in which diodes alternately direct currents through zero-length paths or transmission line paths having predetermined electrical lengths is provided. All the diodes of a path are in series with a common polarity relative to a D.C. diode forward bias source applied between the input and output ends of the network. Each alternate path has a pair of diodes with the collector-emitter internal circuit path of a transistor therebetween. In the case of the alternate path containing a transmission line section, the transmission line section is also connected in series in the path between the two diodes. Binary voltage control signals for controlling the direction of current through a pair of alternate paths are applied to the bases of the transistors in the path. The normal and the complemented signal, respectively, are applied to the bases of one and another of the transistors. 
    
    
     BRIEF DESCRIPTION OF THE DRAWING 
     The single FIGURE of the drawing is partially an electrical schematic and partially a block diagram schematic of a phase shifter network in accordance with the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring now to the single FIGURE of the drawing, a diode switched phase shifter network 10 has an R.F. input terminal 12 and an R.F. output terminal 14. The input applied to terminal 12 is an R.F. signal which is to be subjected to selectively controllable phase shift increments which are selectively introduced by a 180° increment shift stage 16 and a 90° increment shift stage 18. Selective control of the magnitude of phase shift introduced by stages 16 and 18 is provided by binary control signals BIT 180 , BIT 180  for stage 16 and binary signal BIT 90 , BIT 90  for stage 18, as symbolically indicated on the drawing. For simplicity of explanation, network 10 is shown as containing two increment shift stages. However, it should be understood that the typical practical embodiment will contain a total of 4 or 5 such stages in order to enable selection of phase shift angle with fine resolution. 
     180° phase shift stage 16 is comprised of two parallel electrical circuit paths between an input junction point 20 and an output junction point 22. The left-hand (as appears on the drawing) path is the 180° phase shift path 24 comprised of a diode 26, the collector-to-emitter internal circuit of a low frequency transistor 28, a microstrip transmission line section 30 having an electrical length of 180° at the R.F. frequency, and another diode 32. The right-hand path is the zero-shift path 34 comprised of a diode 36, the collector-emitter internal circuit of a low frequency transistor 38, and a diode 40. The binary control signals for stage 16, which consists of the regular binary voltage signal BIT 180 , and the complemented binary voltage signal BIT 180 , are applied to the bases of transistors 28 and 38, respectively, via suitable driver stages 42 and 44. Driver stage 42 is so constructed that when the signal BIT 180  is in its HIGH state, the base of transistor 28 will be essentially grounded, causing saturation conduction in the collector-emitter internal circuit thereof. When signal BIT 180  is in its LOW state, a positive polarity voltage is applied to the phase of transistor 28 causing the collector-emitter internal circuit of the latter to be open circuited. Driver stage 44 applies signal BIT 180  to the base of transistor 38 in a like manner. Both driver stages 42 and 44 are coupled to the respective bases through R.F. decoupling impedances 46 and 48, respectively. 
     90° phase shift stage 18 is identical to stage 16 except that the transmission line section 50 in its phase shift path has an electrical length of 90°. Because of this the identical components thereof have been given the same reference numerals as their counterparts in 180° shift stage 16, but with a postscript &#34;a&#34;. 
     Diodes 26, 32, 36, 40, 26a, 32a, 36a and 40a are all poled such that their forward direction of conduction is from input terminal 12 to output terminal 14. Similarly, the polarity type of transistors 24, 34, 24a, and 34a and the poling of their respective collector-emitter internal circuit paths are so chosen for forward conduction in the direction from input terminal 12 to output terminal 14. For exemplary purposes it will be assumed that the voltage drop across each diode is 0.7 volts and the voltage drop across the collector-emitter path of each transistor is also 0.7  volts. A positive diode forward conduction bias voltage E+ of a magnitude sufficient to provide the aggregate of the diode and transistor drops is introduced into network 10 at a circuit junction point 52 via an R.F. choke 54. This D.C. bias potential is coupled to a ground return at a circuit junction point 56 via another R.F. choke coil 58. 
     Diodes 26, 32, 36, 40, 26a, 36a and 40a are conventional R.F. diodes. Transistors 28, 38, 28a, and 38a are conventional pnp-type low frequency transistors such as Style No. 2N2909 available from a number of major transistor manufacturers. Network 10 is made of conventional high density packaging employing microstrip delay lines, and diode and transistor chips mounted directly upon the microstrip structure in a way which permits a construction with all connections of essentially zero electrical length at R.F., except where the delay line sections 30 and 50 are in the circuit. 
     As a matter of design choice, R.F. decoupling impedances 46, 48, 46a, and 48a may be either R.F. choke coils or resistors. By using choke coils, maximum decoupling of the R.F. signal out through the driver stages is achieved, but the resulting circuit construction must be implemented by the attachment of the R.F. coils, which makes high density packaging of circuit 10 difficult. However, it is a feature of the present invention that a very small amount of control current is required between the respective driver stage and the base of the respective transistor, and therefore it is possible to use resistive lines or discrete resistors to provide the desired isolation of the R.F. and D.C. networks. Use of resistive lines or discrete resistors further makes the network amenable to high density packaging. Also, it should be noted that what makes resistor elements usable is that the D.C. current gain of the transistor offsets the D.C. loss incurred by the use of the resistor, which will have a value which is large compared with the characteristic impedance of the transmission line. 
     In the operation of network 10 the digital bit signals can selectively control the configuration of paths from R.F. input terminal 12 to R.F. output terminal 14 to provide any combination of 0°, 90°, 180°, 270° phase shift. For example, to provide a 90° phase shift a binary control signal combination of BIT 180  = LOW, BIT 180  = HIGH, BIT 90  = HIGH, and BIT 90  = would be applied. In shift stage 16, the application of a LOW BIT 180   signal to driver stage 42 causes the collector-emitter internal circuit of transistor 28 to be open circuited, so that no forward conduction is possible to diodes 26 and 32. Conversely, the HIGH BIT 180  signal to driver stage 48 drives transistor 38 into saturation conduction through its collector-emitter internal path and the forward biased diodes 36 and 40 conduct the R.F. signal through zero shift path 34. In increment shift stage 18 the HIGH BIT 180  signal causes the R.F. signal to travel through the 90° phase shift transmission line 50 and the LOW BIT 90  causes zero shift path 34a to be open. It is to be appreciated that a key factor in the effective operation of network 10 is that the transistors when driven into saturation exhibit an extremely low collector-to-emitter R.F. loss, and therefore can be placed directly in the R.F. path. 
     It will be appreciated that several of the details of construction of network 10 are only one way in which an effective network may be implemented. The locations of the transistor and transmission line in the 180° paths 24, 24a could be reversed. The D.C. bias potential, and the corresponding forward conduction polarity of the diodes and the collector-emitter internal circuits of transistors need not run in the same direction as the R.F. flow. The transistors could be of the npn polarity type, provided that the polarity of diodes is changed to have a corresponding forward conduction direction. 
     An important advantage of the invention is the D.C. power savings. Using the previous exemplary voltage drops of 0.7 volts for both transistors and diodes, the E+ power supply for a network having an average number of conducting diodes = 10 would be equal to or greater than 10.5 volts. Using the same method of calculation as earlier described herein, the power source required for such a circuit would be 1.05 watts or a saving of almost 80% over the described prior art parallel drive approach. 
     Another important feature is the simplicity of the R.F. circuit. Only two bias lines are connected directly to the R.F. path, and no series capacitors are necessary between increment shift stages. In addition, the amount of decoupling between the R.F. path and the control lines which drive the transistors is very small. The end result is that the construction yields a very low insertion loss. Further, because of the lack of frequency-sensitive elements, the circuit design is capable of wideband operation. These results have been experimentally verified, and the insertion loss of a transistor stage has been determined to be significantly less than 0.1 db. The 0.1 db amount has been found to be that of the circuit elements required with the prior art approach of separate forward biased drivers for individual diodes, or for sets of several diodes, which are no longer necessary in the present configuration.