DE1912852C3 - Reflection amplifier for very short electromagnetic waves - Google Patents

Description

with R as the amount of negative resistance is at least approximately fulfilled

4. Reflection amplifier according to claim 2, characterized in that the inductance L is dimensioned such that the relationship

_ R

ω - y

with R as the amount of negative resistance is fulfilled

The invention relates to a reflection amplifier for very short electromagnetic waves with a tunnel diode as a semiconductor element with negative resistance characteristics connected to a circulator is switched on to which, in addition to the signal source, a consumer (load resistor) is connected.

In amplifiers of this type, the negative characteristic of the semiconductor element is used for undamping for example, the positive formed by the parallel connection of a generator and a consumer Conductivity exploited. A particularly suitable element of this type is the tunnel diode, whose Characteristic curve is known to have a falling range. Is such a tunnel diode in one Operating point, which is set on this falling branch of the characteristic curve, then it represents a negative resistance, which is used in the manner already described for reinforcement purposes can be. However, the negative branch of a tunnel diode characteristic is usually only in a relatively small one Regarding the voltage range as linear. If a larger signal is fed to the tunnel diode, which occurs in the If a larger output power is often desirable, then an absolute value occurs greater negative resistance. The increasing amount of negative resistance is conditional but a corresponding decrease in gain.

The invention is based on the object of overcoming these difficulties in a simple manner.

25 Based on a reflection amplifier for very short electromagnetic waves with a tunnel diode as a semiconductor element with negative resistance characteristics, which is connected to a circulator to which a consumer (load resistor) is connected in addition to the signal source, this object is achieved according to the invention in such a way that A transforming network is connected between the tunnel diode and the circulator, the transforming network advantageously consisting of a capacitor of capacitance C connected in parallel with the tunnel diode and a coil of inductance L connected in series with the parallel connection

The capacitance C is advantageously dimensioned in such a way that at the signal frequency ω the condition

with R as the amount of negative resistance is at least approximately fulfilled

The inductance L is advantageously dimensioned such that the relationship

1 ^row

U) L = -

with R as the amount of negative resistance is fulfilled. The inductance L can be formed here, for example, by the lead inductance L _{0 of} the tunnel diode and by suitably selected external inductances Li.

The invention is explained in more detail below with reference to figures

Fig. 1 shows schematically the current-voltage characteristic of a tunnel diode. When the tunnel diode is operated with an amplifier, its operating point is usually placed in the steepest part of the negative branch (point A). The amount of the negative resistance is minimal at operating point A (R = R _m in) - If the tunnel diode is controlled by a signal, the amount of the negative resistance remains unchanged if the signal amplitudes are sufficiently small. With increasing signal amplitude U ₁ , the amount of the negative increases

Resistance R, however, increases rapidly (see FIG. 2). In the F i g. 2 is the ratio of negative resistance

plotted graphically for the minimum resistance (R / Rmin) as a function of the maximum signal amplitude O _1.

F i g. 3 shows schematically a tunnel diode amplifier

ker with a circulator. The signal wave coming from the signal generator 1 is fed to the tunnel diode 3 via the circulator 2. The signal wave is amplified at the negative resistance of the tunnel diode, reflected and reaches the load resistor 4, which is connected to the arm of the circulator that follows the arm on which the tunnel diode 3 is located. The power gain Γ that can be achieved with this amplifier is given by the expression

Γ =

R _a + RR _a -R

Ra here means the value of the load resistance, which is identical to that of the generator resistance and the wave resistance of the circulator. Changes in the amount of negative resistance that are caused by modulation turn into corresponding ones

Changes in gain noticeable. According to the invention, a transforming network S is connected between the circulator 2 and the tunnel diode (see FIG. 4) which is dimensioned such that changes in the amount of the negative resistance do not affect the gain. In this way, the negative resistance generated by the quantum mechanical tunnel effect is not used in its original size for amplification, but the amplification only takes place at the transformed negative resistance. The network 5 consists in the simplest case (see FIG. 5) of a capacitance C connected in parallel with the negative resistance -Ä <0 and an inductance L connected in series. The capacitance C is dimensioned so that the condition is met at the signal frequency ω

is at least approximately fulfilled For the inductance L, the relationship applies

Resistance to 10% decrease in gain is less than 0.1 dB.

7 shows the equivalent circuit diagram of the tunnel diode. Here - R _{n is} the resistance occurring at the pn junction, C _{n is} the capacitance of the pn junction, L _{0 is} the lead inductance of the tunnel diode and Ro is the rail resistance of the tunnel diode. It is advantageous here to design the capacitance C _n , which is parallel to the negative resistance −A <0, in such a way that the condition

L-I- *

35

6 shows schematically in the complex impedance level the transformation of the negative resistance -R <0 brought about by the elements C and L. This negative resistance is caused by the capacitance connected in parallel with the susceptance value

The inductance L with the inductive reactance is transformed along the circular arc 6 into point a

55

45 causes a further transformation to the real value

-. Is now by overdriving the tunnel diode

(or due to a temperature-related small shift in the operating point, for example) the amount of the negative resistance is effectively greater, so the transformation path begins in FIG. 6 with the value - R on the negative real axis. The negative resistance 'assumed in this example to be 10% greater than R is transformed along the circular arc 7 into the point b. If the value of the capacitance C remains the same, the two points a and b lie on the circular arc 8. One recognizes directly from F i G. 6 that the real parts of the impedances corresponding to points a and b are practically the same size. Because the inductive resistance remains the same, however, the impedance corresponding to point b is no longer in the negative real

Resistance - transformed, but into a point

c corresponding impedance. However, it can be shown that this almost does not affect the gain by the assumed increase in the amount of the negative

65 ι j is at least approximately fulfilled If one assumes that the internal limit frequency f _{g is} approximately constant due to the process, this condition is automatically fulfilled when the signal frequency approaches the internal limit frequency

and

d. i.e. the tunnel diode does not have an external capacitance However, an external inductance is switched on. It can thus be used as the capacitance of the transforming network use the capacity of the prr transition, which is inevitable anyway. The series inductance of the transforming Network is controlled by the feed line inductance Lo of the tunnel diode and an external connected Inductance Li is formed so that the relationship

ω (L ₀ + L ₁ ) = y

results in the inductance L \ ist in the equivalent circuit diagram according to FIG. 7 drawn in dashed lines

In the following, a numerical example is used to indicate the way in which the transforming network is calculated in accordance with the teaching according to the invention. The specified and determined values for the individual components are entered in Fig. 8, which shows the equivalent circuit diagram of the tunnel diode and the connected network. An internal limit frequency fgi - 10 GHz and a resistance R _n (amount) - 50 Ω are assumed for the tunnel diode. From the equation

JQi 1

"2 π C" Ä "

follows for

C =

60 " 2nf. _R R"

¹⁰ -50

: 0.3pF.

The tunnel diode is used as an amplifier at 100 MHz. According to the invention, an external capacitance C is to be connected, which is to be dimensioned as follows:

u) C = -. —Τ;

I K I

Hi ^^ TCS ^^^

it follows

C =

\ R.

= 30 pF. it follows

L =

in the

2 <"

4OnH

The external inductance L is calculated according to the teaching according to the invention in the following way:

, Kl.

<uL ■ = —r—,

As a result, it should be noted that the external

switched on reactances, which the transforming

Form a network so large at the given frequency

are that the transformation through the reactances of

ίο tunnel diode itself is negligible.

For this purpose 4 sheets of drawings

Claims (3)

Patent claims: 1. Reflection amplifier for very short electromagnetic waves with a tunnel diode as a semiconductor element with negative resistance characteristics which is connected to a circulator to which a consumer (load resistor) is connected in addition to the signal source, characterized in that between the, ₀ tunnel diode and the circulator transforming network is switched on 2. Reflection amplifier according to claim 1, characterized in that the transforming new work consists of one of the tunnel diode parallel-connected capacitor of capacitance C and a coil of inductance L connected in series to the parallel circuit 3. Reflcxionsverstirker according to claim 2, characterized in that the capacitance is dimensioned so that the condition at the signal frequency ω