DE665022C - Resistance capacity-coupled amplifier - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
SEPTEMBER 16, 1938

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21a ² GROUP 18

Radio Corporation of America in New York, V. St. A.

Resistance capacitance coupled amplifier

Patented in the German Empire on April 30, 1935

is used.

The invention relates to resistance capacitance-coupled devices Amplifier circuits in which the frequency of the signals to be transmitted is within wide limits, for example between 20 Hz and 1 megahertz, moved.

As is known, an amplifier of the aforementioned type contains one or more stage coupling arrangements, an output or anode coupling resistor, an input or grid coupling resistor and comprise a coupling capacitor. Such a coupling arrangement can, for example are used between two amplifier stages or between one amplifier stage and an output circuit such as a transmission line.

When designing a resistance-capacitance-coupled amplifier for transmission The coupling or grid block capacitor plays a role in a wide frequency range important role for the position of both the upper and the lower limit frequency.

The lower part of the frequency curve of a coupling arrangement with resistance and Capacitance elements can be improved by enlarging the coupling capacitor, but not without a substantial increase in cost. Subject of the invention however, measures are taken to achieve this improvement without increasing the size of the coupling capacitor to achieve. The invention also aims to improve a resistance-capacitance-coupled amplifier with regard to the gain and the entire frequency curve.

In explaining the concept of the invention, reference should be made to the drawing which contains the following representations:

Fig. Ι is the circuit diagram of an amplifier with a stage coupling arrangement according to the invention;

Fig. 2 is a simplified equivalent circuit diagram of Fig. 1;

Fig. 3 shows in a diagram the effect of the coupling arrangement used in Figs. 1 and 2;

As a further exemplary embodiment, FIG. 4 shows a modified circuit according to FIG Invention.

In Fig. Ι there are 10 and 11 discharge tubes with a large gain factor (small diameter

grift), 12 the input and 13 the output terminals of an amplifier. The amplifier tube in the first stage 10 is a screen grid tube and contains a control grid a cathode 16, a screen grid 17 Ig an anode (output electrode) 18. Control grid 15 is connected to one of the input terminals 12 via the coupling capacitor 19 and to a grid discharge resistor 20, which is connected to ground 21 via a filter resistor 22. The cathode 16 is equipped with a bias resistor 23, which is also connected to ground. A bypass capacitor 24, located between resistor 22 and the cathode, completes the input circuit of the first stage.

The screen grid receives a positive potential from a voltage source, not shown, via the feed line 25; in similar Way is the anode 18 via the anode circuit 26, in which the anode coupling resistance 27 and a filter resistor 28 are connected to a positive anode voltage source connected. The filter resistor is with a bypass capacitor 29, which is connected to earth and completes the starting circle of the first stage.

The second stage tube 11 preferably also has a high gain and includes a cathode 30, a control grid 3X, a screen grid 32, and a Anode 33, which is connected to one of the two output terminals 13 via the output line 34 is connected, the other via the feed line 35 to a positive voltage source connected.

The input circuit of the tube 11 in the second amplifier stage contains a grid lead 36 and a grid or input coupling resistor 37, the end of which is further away from the grid is earthed. The grid 31 receives a negative bias the resistor 37 from a suitable source, such as that located in the cathode circuit Resistor 38. The screen grid 32 draws its positive voltage via a Feed line 39.

The output circuit of the first amplifier stage is coupled to the input circuit of the second stage through the coupling capacitor 40. The signal voltages occurring at resistor 27 are fed to input resistor 37 through the coupling capacitor. In the case of an amplifier which is intended to transmit a broad frequency band, the coupling capacitor 40 becomes an important factor which is essential in achieving good fidelity of reproduction, in particular at the lower limit of the audio frequency range. For a certain amplifier tube 11 in the second stage, the maximum value <| * | es resistance 37 or R _{g is} fixed, and that

Ipdukt cgi? _s ; that is the lattice circle distortion

J indicates a best frequency can be increased by increasing Cg, as the capacitance of the capacitor 40 is also to be called.

However, since the spatial dimensions of Cg increase at the same time, one soon reaches a point where an increase causes a considerable increase in the circuit capacitance to earth; this acts in parallel to the parallel resistor R _p or resistor 27 and to Rg and determines the distortion occurring at high frequencies for a given combination. For a given earth capacitance, the distortion for the higher frequencies can only be reduced by reducing the parallel resistance, usually R _p . However, this not only reduces the gain of the tube 10 in the first stage, but also requires a larger filter capacity 29 or cf. Therefore, it is usually advantageous to keep Cg as small as possible.

It has been found that the go distortion that arises when the value of the product C _g R _g is small can be substantially reduced by using a small filter capacitance Cf. In the borderline case, by making both the filter impedance 28 or R ₁ and the internal resistance r _{p of} the first amplifier tube 10 infinitely large, the distortion for the low frequencies can be brought to any value and by using the products C _g R _g and C _f R “ equalize each other, even make them zero.

Fig. 2 shows the internal resistance r "of the first amplifier tube 10 together with the voltage μ e _g generated by the tube 10 in parallel with the output coupling impedance R _D and the bridging capacitor C _{1 connected} in series, which forms one branch of the Represent the output circuit, the other branch of which consists of the coupling capacitor C _{g and the Git}

level R _s exists. The voltage occurring along the tube resistance or between the anode and earth is denoted by e _x and the output voltage at the grid resistance by _{e 2} . The currents flowing in the two anode circuit branches are denoted by I ₁ -115 and i _s . designated; the voltage drop generated at the inner tube resistance r _p is equal to the vector quantity (I ₁ + J ₂ ) · r _p . The voltage produced by the first stage or pre-tube is the same

μ · e _g - e _x ■ + · (i _t - \ - i ₂ ) · r _p . (1)

With the help of the equivalent circuit diagram shown in Fig. 2, one can now show by calculation that the voltage e _{s is given} by the following expression:

µ-eg'Rp.-Rp

ι · ω · Cf

where the following expression is to be inserted in the curly brackets:

i · ω · Rp-Cf [ω = angular frequency |

i- tO · R, r- Approx

It can be seen from this that for the smallest possible distortion in the low frequency range the product CgRg must be equal to the productive:

If this condition is met, the expression for e ₂ simplifies to the following:

μ - e _g - R _p

R _p . R, + rp. (Rp

i · ω · Cf

Assuming that r _{O is} greater than R _n and Rg, which is not a restriction, then , if equation (2) is satisfied, e ₂ is essentially frequency-independent even at low frequencies. (In the equivalent circuit diagram, the resistance R _{f is} omitted, ie assumed to be infinitely large. For finite Rf, which is, however, large compared to R ₁ and R _g , the consideration is not significantly changed.)

In a circuit dimensioned according to equation (2), the coupling capacitor have a minimum capacitance and still have the low-frequency end of the frequency curve on a relatively be brought to a great height; in Fig. 3 the gain for low frequencies is shown by the full line Curve 42 shown and to be compared with the dashed curve 43, which is for a Ordinary resistive capacitance coupling applies in which the aforementioned improvement the frequency curve was not performed.

It is noteworthy that the frequency curve 42 can be obtained without changing the size of the to have to increase the capacitor used to achieve curve 43. The improvement can be attached to any amplifier that transmits a certain frequency range, the zero point being the in Fig. 3 shows the lower fundamental frequency of the selected operating frequency range represents. For an ordinary

Capacitor as a coupling element shows the improvement in the frequency curve in Fig. 3 through the obtained frequency ranges A and B , with range B representing the practically usable extension of the range up to a point with permissible distortion. A comparison of the curves shows that a considerable improvement in the frequency curve is achieved in the region of low frequencies without additional arrangements or costs having to be expended or the frequency curve for the higher frequencies being worsened.

In Fig. 4 is an output coupling arrangement for an amplifier for connection shown on a transmission line.

The amplifier or output stage contains two amplifier tubes 45 connected in parallel with a high internal resistance, to which the signal voltages are fed via the input terminals 46 and a coupling capacitor 47 and a grid impedance 48. Resistors 49 are provided in the grid circles to prevent feedback; the grids receive a bias from a suitable source, such as the bias resistor 50 located in the common cathode lead. The circles are closed above ground, as can be seen in the figure. The output circuits of the two tubes 45 are connected parallel to an output circuit 51, in which an output coupling resistor 52 or R _p and a filter n ₀ impedance 53 or R _f, which consists in the exemplary case of a low-frequency choke, are. A high-frequency choke 54 and a current limiting resistor 55 are connected in series with the impedance R _1. Like the screen grid lead 57, the circuit is connected to a feed lead 56 leading to a positive voltage source.

A load circuit 58 is connected to the output terminals 59, which in turn via the coupling capacitor 60 with the

Output coupling impedance R ₁ , are connected.

The load circuit 58 is formed by a transmission line which has a relatively low impedance for signal frequencies. The load line can be viewed as Rg while the Kopp g
treatment capacitor 60 as

is to be seen.

The capacitor 61 is part of the branch circuit containing an R ₁ , and represents C /.

With a pair of tubes of the type RCA 247 and an output line 58, the impedance of which is 50 ohms, with R ₁ , equal to 50 ohms and capacitors C _g and C ₁ of 250 μ ¥ each, a maximum of sensitivity can be achieved at low as well as high Achieve frequencies. Without using the arrangement shown, you need a capacitance of 750 μΡ and a smaller impedance R _p for the coupling capacitor C _g . It can therefore be seen that one achieves a substantial cost saving and at the same time an improvement in the frequency curve if one makes use of the concept of the invention.

In the present example, the impedance of the filter reactor is 53 and the internal one Resistance of the tubes 45 relatively high, as in the previous Fig. 1 and 2 indicated. Since the effect in the

Circuit of Fig. 5 is the same, further discussion about it should be superfluous.

Claims (2)

Patent claims: ι. Resistance capacitance-coupled amplifier with tubes with high internal resistance, preferably screen grid tubes, in which the anode circuit forks into two branches, one of which has an output coupling resistor (R _p ) and in series with it a filter capacitance (C _f ) and the other of which has a coupling capacitance ( C _s ) and a grid or load resistor (R _g ) connected in series, characterized in that the product of the capacitance of the coupling capacitor and the resistance of the load resistor is essentially equal to the product of the output coupling resistance and the capacitance of the filter capacitor. 2. Amplifier according to claim 1, characterized by such a choice of Circle constants that the output coupling resistor occurring voltage is substantially in phase with the voltage generated by the pre-tube. Please refer to the sheet of drawings