DE3744782C2 - Chain amplifier with FETs - has capacitor and earthing impedance in parallel between FET source terminals and earth - Google Patents

Abstract

In addition to a gate, drain and a source terminal, each FET has an induction element for connection of the adjacent gate terminals, while a second induction element is provided for the connection of the drain terminals. A microwave is supplied via an input terminal, while an amplified microwave is passed to the output terminal. Between the drain terminal fo the FET, next to the input terminal and earth potential is a first closure element, while a second one is between the earth potential and the gate terminal of the FET, adjacent to the output terminal. A capacitor (32) with a higher capacitance than that of the gate-source of each FET (3), and an impedance (33) for d.c. earthing are in parallel between the source terminal (6) of each FET and the earth potential.

Description

The invention relates to an operating voltage supply circuit according to the generic term of claim 1.

In order to supply an operating voltage to a microwave circuit, for example an FET chain amplifier operating in the microwave range, an operating voltage supply circuit as shown in FIG. 1 and disclosed in Japanese Patent Publication 2,333,912 / 85 can be used. This has transmission lines 24, 25 , a resistor 26 , capacitors 27, 28 and 29 , and an input terminal 30 and an output terminal 31 .

In this operating voltage supply circuit, two transmission lines 24, 25 are provided between the input terminal 30 and the output terminal 31 . The transmission line 24 is grounded at the right end via a series circuit comprising the resistor 26 and the capacitor 27 and at the left end via the capacitor 28 . The transmission line 25 is grounded at the left end via the capacitor 29 . In this arrangement, a low-pass filter consisting of the transmission lines 24, 25 and the capacitors 28, 29 can be regarded as grounded at its right end via a series connection of the resistor 26 and the capacitor 27 . The input terminal 30 is connected to a voltage source VS and the output terminal 31 is connected to a broadband amplifier such as a FET chain amplifier (not shown).

The transmission lines 24, 25 and the capacitors 28, 29 , which constitute the low-pass filter, have selected parameters in such a way that the cut-off frequency of the low-pass filter is lower than a desired frequency band. The capacitor 27 has a capacitance chosen such that it produces an impedance that is small enough in the desired frequency band. As a result, the impedance seen from point A in Fig. 1 is substantially infinite in a desired frequency band. The impedance, seen from the output terminal 31 to the input terminal 30 , is substantially equal to the value of the resistor 26th

The output terminal 31 is accordingly terminated by the resistor 26 in the desired frequency band, making it possible to stabilize the operation of the associated broadband amplifier. Furthermore, if a desired DC voltage from the voltage source VS is applied to the input terminal 30 , an operating voltage can be supplied from the output terminal 31 to the broadband amplifier via the transmission lines 24, 25 without any voltage drop.

However, such an operating voltage supply circuit in the above-mentioned embodiment is disadvantageous in that the impedance viewed from point A depends heavily on the impedance of the voltage source VS connected to input terminal 30 , if the low-pass filter does not have a sufficient number of stages to match the impedance, the point A made to make infinite. Since the impedance, as seen from the output terminal 31 to the input terminal 30 , depends on the impedance of the voltage source VS, the properties of the amplifier are determined by the voltage source used. Sometimes the operation of the broadband amplifier becomes unstable by the operating voltage supply circuit.

It is therefore the task of the present Er invention, an operating voltage supply circuit to create at which of the output terminal seen from the input terminal  Impedance can be kept constant regardless depending on the impedance of one with the Connected to the input terminal Voltage source to impairment the microwave voltage supplied with the operating voltage Circuit by the voltage source to ver prevent.

To solve this problem, the operating voltage supply circuit according to the preamble of claim 1 a first transmission line, one end of which is connected to the input terminal, a second transmission line, one end of which is open and their other end with the other end the first transmission line and the output terminal is connected, and at least one resistance between a point on the first transmission line and a point on the second transmission line is switched.

With this operating voltage supply circuit will be a microwave by one consumers connected to the output terminal circuit to the operating voltage supply circuit penetrated, of which the connecting the first and second transmission lines Resistances absorbed. The one with the tension source connected end of the first transmission line is grounded via the condenser with respect to a microwave.  

Accordingly, that of the output terminal off to the input terminal considered impedance kept constant are independent of the impedance of the Voltage source. This means that the Properties of the consumer circuit are not affected by the voltage source be what makes it possible for consumers stabilize circuit.

The invention is based on execution shown in the figures examples explained in more detail. It shows

Fig. 1 shows a known operating voltage supply circuit,

Fig. 2 is an equivalent circuit diagram supply circuit of a first embodiment of the operating voltage according to the invention,

Fig. 3 is an equivalent circuit diagram of a second embodiment of he inventive operating voltage,

Fig. 4 is an equivalent circuit diagram of a third embodiment of the supply voltage supply circuit according to the invention, and

Fig. 5 is an equivalent circuit diagram of a fourth embodiment of the inven tion operating voltage supply circuit.

In Fig. 2, a first embodiment of the operating voltage supply circuit according to the invention is shown. A first and a second transmission line 43 or 44 are arranged between the input terminal 30 and the output terminal 31 . Resistors 45 and 46 , a capacitor 47 and a T branch 48 are also provided. The points a and b on the transmission line 43 and the points a 'and b' on the transmission line 44 correspond to predetermined positions. One end of the transmission line 43 is grounded through the capacitor 47 and connected to the input terminal 30 , and its other end is connected via the T-branch 48 to the output terminal 31 , which in turn is connected to an operating voltage terminal of a circuit which requires an operating voltage. One end of the second transmission line 44 is open and its other end is connected to the output terminal 31 via the T-branch 48 . The resistor 45 connects between the predetermined point a on the first transmission line 43 and the predetermined point a 'on the second transmission line 44 , and the resistor 46 connects the predetermined point b on the first transmission line 43 with the predetermined point b' on the second transmission line 44 . The lengths of the first and second transmission lines 43 and 44 are chosen so that they are equal to each other. The electrical length between the output terminal 31 and the point a is equal to that between the output terminal 31 and the point a '. Accordingly, the electrical length between the output terminal 31 and the point b is located between the output terminal 31 and the point b '. The capacitor 47 has a capacitance in which the impedance generated is sufficiently small in a desired frequency band.

In the operating voltage supply circuit formed in this way, a microwave received via the output terminal 31 from a circuit connected to it is divided equally by the T-branch 48 . The two halves of the microwave thus divided each run through the first and second transmission lines 43 and 44 to the input terminal 30 , whereby they are in phase with one another and have the same amplitude without being consumed by the resistors 45 and 46 . These microwaves are entirely reflected at the left ends of the transmission lines 43 and 44 and return to the output terminal 31 . however, since the left end of the first transmission line 43 is grounded through the capacitor and the left end of the second transmission line 44 is open, the reflected microwaves are no longer in phase with one another and have the same amplitude. Therefore, the reflected microwaves at points a and a ′ and also at points b and b ′ are out of phase. Accordingly, the reflected microwaves are consumed by the resistors 45 and 46 and do not return to the output terminal 31 .

As a result, the impedance seen from the output terminal 31 to the input terminal 30 is equal to the equivalent resistance determined by the resistors 45 and 46 and the first and second transmission lines 43 and 44 in a desired frequency band. Since the left end of the first transmission line is grounded 43 for microwave via the capacitor 47, is from the output terminal 31 from toward seen with the input terminal 30 impedance kept constant regardless of the impedance of the terminal to the input 30 operating voltage supply connected source. Furthermore, if a DC voltage is applied to the input terminal 30 , the operating voltage can be supplied from the output terminal 31 to the circuit like a broadband amplifier via the first transmission line 43 without any voltage drop.

Thus, this operating voltage supply circuit not only keeps the impedance of the output terminal 31 from the input terminal 30 toward seen constant but can also work without being affected by the connected to the input terminal 30 voltage source.

Fig. 3 is an equivalent circuit diagram of a second embodiment of the operating voltage supply circuit according to the invention. Here, first and second transmission lines 43 and 44 with different lengths are used. Therefore, the electrical lengths between the output terminal 31 and point b on the one hand and between the output terminal 31 and point b 'on the other hand are different from each other. Accordingly, the electrical lengths between the output terminal 31 and the point a on the one hand and between the output terminal 31 and the point a 'on the other hand are different.

In such an operating voltage supply circuit, a microwave received via the output terminal 31 from the circuit connected to it is evenly divided by the T-branch 48 . The two halves of the so-divided microwave run through the first and second transmission lines 43 and 44 to the input terminal 30 . Since the phases of the microwaves at point b and at point b 'are different from one another and also the phases at point a and at point a', the microwaves are partially consumed by resistors 45, 46 and their remainder settles to the left End of the transmission lines 43 and 44 out. Each microwave is fully reflected at the left end of the first and second transmission lines 43, 44 and then runs back towards the output terminal 31 . The two microwaves reflected in this way are out of phase. They are therefore consumed by the resistors 45 and 46 and do not reach the output terminal 31 .

As described above, a microwave that has passed output terminal 31 is partially consumed by resistors 45, 46 as it propagates toward input terminal 30 . The rest of the microwave is reflected at the left end of the first or second transmission line 43, 44 and then consumed by the resistors 45, 46 . As a result, the operating voltage supply circuit of FIG. 3 operates in the same manner as that of FIG. 2.

Fig. 4 shows a third embodiment of the operating voltage supply circuit according to the invention. This differs from the operating voltage supply circuit according to FIG. 2, in that capacitors 49 and 50 are each connected in series with one of the resistors 45 and 46 , respectively.

In this exemplary embodiment, the impedance of the series circuit comprising the resistor 45 and the capacitor 49 is determined by the capacitance of the capacitor 49 . This also applies to the series circuit from the opposing stand 46 and the capacitor 50th Accordingly, the level of consumption of the microwaves by the resistors 45 and 46 can be changed by suitable selection of the capacitors 49 and 50 . Thus, the impedance seen from the output terminal 31 towards the input terminal 30 can be set to a desired value.

Fig. 5 shows a fourth embodiment of the operating voltage supply circuit according to the invention. This differs from that according to FIG. 2 in that the first transmission line 43 is represented by inductors 51 and capacitors 52 and the second transmission line 44 by inductors 53 and capacitors 54 . Instead of the first and second transmission lines 43 and 44 , concentrated constant circuit elements, such as inductors 51, 53 and capacitors 52, 54 are used, which allow the formation of a smaller operating voltage supply circuit.

While two resistors are used to connect the transmission lines in the exemplary embodiments according to FIGS. 2 to 5, one or more resistors can also be used in order to achieve the same effect.

The operating voltage supply circuit is not can only be used for broadband amplifiers, but can also be used for high power amplifiers and oscillators are used.

Claims (4)

1. Operating voltage supply circuit for microwave circuit, in particular a FET chain amplifier, with an input terminal connected to a voltage source, which is grounded via a capacitor, a device connected to the microwave circuit, to which the operating voltage can be supplied, output terminal ( 31 ), and transmission lines Draws a first transmission line ( 43 ), one end of which is connected to the input terminal ( 30 ), a second transmission line ( 44 ), one end of which is open and the other end of which is connected to the other end of the first transmission line ( 43 ) and the output terminal ( 31 ) is connected, and at least one resistor ( 45; 46 ) connected between a point (a; b) on the first transmission line ( 43 ) and a point (a ';b') on the second transmission line ( 44 ) is switched. 2. Supply circuit according to claim 1, characterized in that the first and the second transmission line ( 43, 44 ) have the same length, and that the resistance ( 45; 46 ) between points on these lines at the same distance from the output terminal ( 31 ) is switched. 3. Supply circuit according to claim 1 or 2, characterized in that a capacitor ( 49; 50 ) is arranged in a series circuit to the resistor ( 45; 46 ). 4. Feed circuit according to claim 1, characterized in that the first and the second transmission line ( 43, 44 ) have different lengths.