DE1541519C - Angle modulation night transmission system - Google Patents

Description

did the system very much because there were changes and Aging effects on the receiving side and the transmitting side are similar and thus compensating can affect. The use of negative feedback also ensures a large dynamic range. In a further development, the invention proposes that the transmission demodulator consists of an amplitude modulator for the FM-modulated carrier wave, a demodulator door the amplitude- and FM-modulated

tion stage.

When an analog signal, e.g. B. a voice signal, from a transmitting point to a receiving point by means of a Carrier wave is transmitted occurs within the

In the following, angle modulation is understood to mean frequency modulation and phase modulation. the
The following explanation largely takes up the
Frequency modulation reference, in which, however, no one-io component, a restriction connected to it, can be seen. . Level verification level and a prestressing sum-

In the case of an angle modulation message transmission stage for the amplitude modulator to the summation system it is already known to improve the output voltage of the level detection Linearity of a klystron modulator is a partial stage and a fixed bias. Through of the modulated carrier signal via a demodulator 15 this training has the advantage that the

The course of the hyperbolic strain curve can be set very easily by changing the fixed preload is.

Finally, several are connected in series

Message transmission path from the transmission point 20 amplitude modulators, whose respective preamble over the transmission link to the receiver voltage summing stages are coupled in parallel to the level after each noise component in the signal wave, a development of the constant variable. Subject matter of the invention also given in an FM system. This gives the signal-to-noise ratio of the reception the advantage that the compression ratio within the signal is smaller when the amplitude of the message is further limited by a corresponding number of analog signals that can be set in the emitted modulated amplitude modulators.
Carrier wave is present, becomes smaller. It is already
in well-known Japanese patent application 12 812/1965 discloses a communication system
described, according to which to remedy this difficulty- 30
the components that have a small amplitude
of the analog signal to be transmitted on the viewing side
compared to the high amplitude fractions
are raised, so that one obtains an amplitude compression, whereas on the receiver side 35 embodiment of the invention,
the amplitude of the receiving analog signal corresponding to the in FIG. 1 illustrated embodiment

an amplitude compression on the transmission side, which had a signal input drive belonging to an FM transmission stage, is stretched so that the original analog signal is received on the terminal 11 for a low-frequency message capture side. output signal, for example a voice signal; With this conventional system, however, one can use 4 ° tion circuit 12, which does not receive sufficient companding at an input terminal, low-frequency message input signal from the input terminal 11 apart from the fact that the conventional system; an FM modulator 13 a large number of Requires construction stages. with a voltage-controlled oscillator

The object of the invention is such a Licher frequency for generating an FM-modulated formation of an angle modulation message 45 carrier wave; a power amplifier 15 for the power transmission system that can be used on the transmission side and amplification of the modulated carrier wave and for Ausauf the reception side non-linear circuits with transmission of the amplified signal via a transmission-equal dynamic characteristic. antenna 14; An amplitude limiter 16 for limiting this object is achieved according to the invention by limiting the amplitude of a returned portion of the modulating signal contained in the transmission 17 for demodulating the output oscillation of the modulating signal contained in the transmission 5 ° modulated carrier wave and a transmission demodulator waveform

The invention is illustrated below on the basis of preferred exemplary embodiments with reference to Drawing explained.

F i g. 1 is a block diagram of an embodiment of the invention,

F i g. 2 shows a characteristic curve to explain the mode of operation of the invention and

F i g. 3 is a block diagram of a modified one

demodulator has a hyperbolic expansion characteristic and the feedback signal of the subtraction circuit in phase opposition to the message input signal and that for dynamic expansion 55 of the received demodulation signal, the characteristic of the receiver demodulator that of the transmit demodulator is equal to. By using a feedback in a negative feedback sense, a hyperbolic one has an effect

Amplitude limiter 16 and for the return of the demodulated output signal to the respective other input of the subtraction circuit 12.

The transmission demodulator 17 comprises an amplitude modulator 171 for superimposing an amplitude-modulated component on the frequency-modulated carrier signal which is supplied by the amplitude limiter 16, a frequency discriminator

Dynamic expansion in the demodulating back ^6o nator 172 for demodulating the amplitude modulation

Leading branch as the dynamic compression of the transmission signal lated carrier wave from the output of the modulator 171

out. On the receiving side, the demodulation signal can be passed on to the

like hyperbolic expansion the original post-subtraction circuit 12, a level detection stage 173

recover directional signal. By use with a band pass filter, detection circuit and

Exactly identically constructed demodulators on the ⁶ - ^s a smoothing capacitor, so that an output

On the one hand, the sending and receiving side are voltage as a measure of the level of the output signal

one of the frequency discriminator 172 is generated by using similar circuitry, and

substantial simplification; In addition, the stabilizing unit is a bias summing stage 175 for summing

mation of a supplied via a terminal 174 from a bias voltage source, not shown Bias voltage with the output voltage of level detection stage 173 and for applying the total voltage as a modulating signal for the amplitude modulator 171.

Within the circuits of the invention, the amplitude modulator 171 can be in the form of a push-pull modulator be constructed. A demodulator is used as the frequency discriminator 172, which responds not only to the signal frequency but also to the amplitude, e.g. B. a Foster-Seeley circuit. The level detection stage 173 generates a DC output voltage which is the mean value of the Amplitude of the low frequency output signal of the frequency discriminator 172 is proportional.

If the level of the low-frequency signal of the frequency discriminator 172 is comparatively small, the level of the low-frequency modulating signal for the modulator 13 is essentially the level of the input signal because the subtraction voltage is small. In contrast, if the The level of the low-frequency signal of the frequency discriminator 172 is large, the level of the low-frequency becomes The modulating signal for the FM modulator 13 is compressed as compared with the case of one small input level, since a large subtraction voltage is applied to the subtraction circuit 12. The amplitude characteristic of the modulation process can thus be used as an inverse function of the characteristic of the transmitter demodulator, since the FM modulation of the transmitter is caused by negative feedback is controlled. So if the dynamic strain curve of the transmit demodulator is hyperbolic, For the frequency modulation, a dynamic compression characteristic is obtained, that of the inverse function corresponds to the above-mentioned hyperbolic characteristic.

The following designations apply :. ,

m (t) the message input signal,

X (t) the modulating signal for the FM modulator 13

at the output of the subtraction circuit 12,
μ is the modulation index of the modulator 13,
M is the control signal of the amplitude modulator

171,
β is the demodulation index of the demodulator 172,

y (r) is the output signal of the demodulator 17,
e (t) is the modulation signal in the modulated carrier wave,

A is the overall gain of level verification stage 173,

B the bias voltage applied to terminal 174.

so

1 + μ · β ■ M

e (t) = Km (t).

According to equation (6), the modulation signal e (t) is proportional to the input signal m (t) within a short time interval. If μ » β · Μ , the following applies approximately

K =

1 + μ- ß- M ■ ß- M '
It follows from equations (6) and (7)

The following applies to the control signal M.

M = AY (t) + B.

Since the frequency discriminator 172 not only on frequency changes, but also on changes in amplitude responds and produces an output signal that changes in proportion to both fluctuates, the signal level is given by the following relationship:

Y (t) = MX {t) = (AY (t) + B).

By resolving this relation for Y (t) one obtains

Y (t) =

It can be seen from this that the output level Y (t) of the transmission demodulator 17 is represented by a hyperbolic function of the input level X (t) (of the low-frequency analog signal which is contained in the modulated carrier wave). The input level X (t) is thus converted into the output level Y (t) by means of hyperbolic expansion.

Since the variable M belongs to a strain curve, the modulation signal has an amplitude compression according to equation (8). If one substitutes equation (8) in (3), one obtains for the demodulation signal Y '(t) on the receiving side

Y '(t) = β ■ M

β · Μ

The following equations apply:

e (t) = μ ■ X (t). X (t) = m (t) - Y (t). Y (t) = β · M · e (t).

So we get for the modulation signal:

so exactly the input signal.

If the transmission demodulator 17 is used as a receiver demodulator, the signal-to-noise ratio S / N of the received signal picked up at the output terminal of the demodulator 17 is proportional to the above-mentioned signal level X (t) according to the following relationship:
60

S / N = kX (t) (10)

e (t) =

1 + μ β Μ

■ m (t) (4)

with k as a constant. Because the low-frequency analog signal with the level X (t), which is contained in the modulated carrier input wave of this demodulator, with μ and β as circuit constants. The quantity M, * hold, contains a noise component with condi which is frequency-dependent, can in a first approximation as a constant level. Can be viewed independently of time by solving equation (9). Hence: after X (t) and inserting it into equation (10) one obtains

S / N = kY (t) / (AY (t) + B).

(Π)

In Fig. 2, where the signal level Y (t) is plotted on the abscissa and the signal-to-noise ratio S / N is plotted on the ordinate, the relationship of equation (11) is represented by curve H , which forms part of a hyperbola. As can be seen by comparing equations (10) and (11), the signal-to-noise ratio of the received signal according to curve H is improved in that the transmission demodulator 17 has a hyperbolic expansion characteristic according to equation (9). In comparison to a linear dynamic characteristic curve of the transmission demodulator 17, where the signal-to-noise ratio is also represented by a linear characteristic curve according to curve L in FIG. 2, the improvement in the signal-to-noise ratio according to curve // is surprising. Since the total gain A and the bias voltage B can be arbitrarily selected, the improvement in the signal-to-noise ratio according to equation (11) can be made large.

If the improvement in the signal-to-noise ratio is not sufficient, even if the total gain A and the bias voltage B are changed in the manner described, the characteristic curve according to equation (11) can be changed to the form of a hyperbolic characteristic curve of a higher order. According to FIG. 3, which shows such a modification of the invention belong to the Sendedemodulalor 17 three Vorspannungssummierungsstufen 175 ", 175b and 175c in place of the Vorspannungssummierungsstufe 175, on each of α via the terminals 174, 174 b and 174 c which biases Ba, Bb and Bc issue; Amplitude modulators 171a, 171b and 171c which are connected in series and each receive the output voltage of the preceding modulator as the modulating voltage. The signal-to-noise ratio S / N is obtained in a manner corresponding to that in equation (II) by the following relationship:

S / N = kY (I) I (AY (t) + B ₁ ) (AY (t) + B ₂ ) (AY (t) + B ₃ ).

After that, the signal-to-noise ratio can be considerable Dimensions to be improved.

In the context of the illustrated embodiment of the invention, the subtraction circuit 12 serves as Negative feedback stage for the input voltage of the transmit demodulator 17 to the input FM modulator 13. Of course, you can use a summing circuit instead, since the Subtraction circuit 12 intended for generating the algebraic sum of two signal voltages is. In addition, further modifications of the circuit details can be made. the The invention is not dependent on the details of the modulation method itself.

Claims (3)

Patent claims: 1. Angular modulation - communication system with an angle modulator on the transmitter side and with one connected to the same Feedback transmission modulator and a subtraction circuit for the message input signal and the feedback signal, characterized in that for dynamic compression of the modulating signal contained in the transmission waveform, the transmission demodulator (17) has a hyperbolic expansion curve and the feedback signal of the subtraction circuit (12) in phase opposition to the message input signal supplies and that the characteristic curve of the receiver demodulator for the dynamic expansion of the received demodulation signal that of the transmitter demodulator is the same. 2. Message transmission system according to claim 1, characterized in that the transmission demodulator an amplitude modulator (171) for the FM-modulated carrier wave, a demodulator (172) for the amplitude- and FM-modulated Component, a level detection stage (173) connected to it branching off and a bias summing stage (175) for the amplitude modulator for summing the output voltage of the level detection stage and there is a fixed preload. 3. Message transmission system according to claim 2, characterized by several series-connected amplitude modulators (171a, 171 ft, 171 c) whose respective biasing summation stages (175 ", 175 / ?, 175c) are coupled in parallel to the Pcgel detection stage (173). 1 sheet of drawings