DE3037902C2 - Amplitude-modulated transmitter with operating point control of the carrier oscillation (carrier control) - Google Patents

Description

3. Transmitter according to claim 1 or 2, characterized in that the smallest slope of the characteristic (def, d-e'-f) is smaller than the slope of a characteristic (b5) for carrier control without residual carrier value (R) with a degree of modulation (m ) of 500%.

4. Transmitter according to one of the preceding claims, characterized in that the greatest slope is greater and the smallest slope is smaller than the difference (Tm - R) divided by the maximum permissible level value (P _n ) with a degree of modulation (m) of 100% between the associated maximum carrier value with a degree of modulation (m) of 100% utid the residual value

5. Transmitter according to claim 4, characterized in that the smallest slope is zero

6. Transmitter according to one of the preceding claims, characterized in that the greatest slope is equal to that slope of a characteristic curve (b \) which characterizes the degree of modulation (m) of 100%

7. Transmitter according to one of the preceding claims, characterized in that the slope of the characteristic curve (def, d-e'-f) for the maximum permissible level value (Pm) for one hundred percent modulation and for higher level values is equal to zero

8. Transmitter according to one of the preceding claims, characterized in that the characteristic curve (de ~ f, d-e'-f) has straight sections (d, e, f, e ')

9. Transmitter according to one of the preceding claims, characterized in that the steeper part (e ') of the characteristic curve (d-e'-f) is offset in the direction of at least for carrier values (7?) Which are below the maximum value (Tm) of the carrier value larger carrier values compared to a characteristic (b 1), which corresponds to a carrier control without a residual carrier value with a degree of modulation (m) of 100%

10. Transmitter according to one of the preceding claims, characterized in that the level values in the range from zero to approx. 40 or 50% of the maximum permissible level (Pm) are assigned smaller carrier values than corresponds to the straight line (c).

The invention relates to a transmitter as specified in the preamble of claim I. (There and in the following the word "level" always refers to the peak values of the modulation signal.) As Used broadcast transmitters, such transmitters have the advantage that they consume less energy than anode-modulated transmitter without carrier control. This is due to the fact that in the carrier control, the carrier amplitude is reduced when soft music or Speech (quiet program) is broadcast, ii.lt if the level corresponding to the peak values of the modulation oscillation is low Set the program modulation power saved

As in the magazine "Hochfrequenztechnik und Elektroakustik", Volume 47, May 1936, Issue 5, pages 141-147 it would be most advantageous in terms of energy savings if, for example, sinusoidal modulation voltage the mean value of the positive (in one period of the modulation voltage occurring) carrier amplitudes, i.e. the carrier value, would linearly follow the level of the modulation voltage, even down to the level value zero, where then also the associated carrier value would be zero. Since this "ideal" carrier control can cause interference in radio receivers with fading compensation, it has proven to be better, the carrier value only down to a certain residual carrier value in the same direction as the level of the modulation voltage steer.

These known relationships are shown in FIG. 1, where the carrier value T is plotted against the level P of the modulation voltage. In the case of an amplitude-modulated transmitter without carrier control, the carrier value T is always equal to the maximum carrier value Tm in accordance with the straight line a, regardless of the level P. If the level fluctuates in this case, but the carrier value T remains constant at Tm , the result is a degree of modulation m that fluctuates with the level P.

In the "ideal"Trägersteuervr> g, however, the carrier value will rent speaking of the straight line b 1 in the same direction controlled by the level P Weil will begin fits in this case, the carrier value Tständigdem level, there is a constant modulation depth of m = 100%. The consequence of this, however, is that at a level value P = 0, the carrier also disappears completely, which in the case of radio receivers with fading compensation leads to undesirable phenomena; such receivers then also largely regulate the dynamics, which is also perceived as annoying.

Therefore, the carrier control with residual carrier has been propagated according to the characteristic curve c in Fig. 1. This straight line runs on the one hand through the carrier residual value R and on the other hand through point A, which is common to all three characteristic curves a, b \, c and the maximum values of the level Pm or . of the carrier value Tm It can be seen that with the characteristic curve c with a fluctuating level, possible degrees of modulation from 0 to 100% can occur, because the characteristic curve c intersects all above the characteristic curve b 1 (for m = 100%) and from the zero point O outgoing (but not shown) beams, which correspond to the modulation degrees from 0 to 100%. The slope of the characteristic curve c results from the difference Tm minus R divided by the maximum permissible level value Pm (for m - 100%). The above-mentioned reference also shows that the characteristic curve c is for specific purposes

can also follow special curves or even rise in an echelon shape. But it is not specified which one Purposes are meant and which particular curves should be involved; also on the mind a stepped characteristic curve has not been included.

The present invention has for its object to find a way, as with one Amplitude-modulated transmitter with carrier control with carrier value saves even more energy can be, as it is with a transmitter with a characteristic curve cent according to FIG. 1 is already possible.

This object is achieved by a transmitter with the features of claim 1. Advantageous Further developments are given in the subclaims. Further details are given on the basis of the figures and a preferred embodiment is included. It shows

F i g. 1 the already mentioned characteristics for the carrier value as a function of the level for known Channel,

F i g. 2 shows the basic course of a characteristic curve for a transmitter according to the invention with a particularly large one Efficiency,

F i g. 3 a modified characteristic curve and

F i g. 4 a diagram for the possible energy savings with a characteristic curve according to Fig. 2 as a function of the residual carrier value and in comparison a Fig. 1.

The characteristic curve according to FIG. 2 for a transmitter with carrier control according to the invention is composed of a flatter part d, a steeper part e and again a flatter part f , which meet at break points B and A , respectively. The bend point B belongs to one minimum value Po of the level to which down the carrier value T along the characteristic part e proportional to the level P is variable corresponding to this characteristic, part e (like the characteristic b 1 g in F i. 1) a degree of modulation of 100% . Below the minimum level Po or below the residual carrier value R , this is independent of the level in accordance with the characteristic curve part . This part of the characteristic curve d with a slight slope, here zero, runs parallel to the abscissa, which corresponds to a degree of modulation m> 500%, namely m = ». Because the carrier value along the characteristic curve part d remains constant regardless of the level, the degree of modulation m is variable here, as in the case of the characteristic curve a in FIG. 1. The characteristic curve part f with a low slope (in particular zero) ensures that the carrier value cannot or hardly rise above the maximum value Tm even at an impermissibly high level (> Pm).

The benefit of a characteristic curve according to the invention, the slope of which preferably increases with increasing level values (steady or discontinuous) up to the maximum carrier value Tm, results from the following consideration:

With a changing level P , carrier values result as they can be seen from FIG. 2 can be read off as the distance between the abscissa and the characteristic curve def. To generate these mean carrier amplitudes (carrier values T) , the greater the carrier values, the more energy is required. The energy required for transmission is therefore related to the area f>"> of the pentagon ORBA-Pm-O in FIG. 2. Since this area around the area of the triangle R-BA-R is smaller than the area OR-A Pm-O in FIG. 1 it is easy to see from a purely visual point of view that the energy requirement for a carrier-controlled transmitter according to FIG. 2 is considerably less than the energy requirement of a carrier-controlled transmitter according to FIG. 1, characteristic curve c .

FIG. 2 shows that characteristic curve def for which the greatest energy savings compared to characteristic curve c in FIG. 1 results if it is assumed that a certain residual carrier value R is not undershot and the degree of modulation of 100% is not to be exceeded. If you are satisfied with a lower energy saving, then another curve can be used instead of the characteristic curve def , provided that its course is below the characteristic curve c, i.e. closer to the abscissa than the characteristic curve c , at least for the level values that occur with the greatest accumulation In the case of radio program modulation, the greatest accumulation of level values occurs statistically in the range from 0 to approx. 40 or 50% of Pm . In this area, the selected characteristic should, if possible, * lie completely below characteristic c . If a characteristic line is chosen that always runs below characteristic line c, the greatest slope of this selected characteristic line is expediently larger and the smallest slope smaller than that of characteristic line C, with only positive gradients being considered

In Fig. 3 is a useful modification of the characteristic of FIG. It has been shown that, in the case of the carrier control, the carrier value cannot always immediately follow a suddenly rising level. There is therefore a sudden one; If the level increases, there is a risk of brief overmodulation. In order to counter this danger, the characteristic curve d-e'-f is preferred, in which the steeper part e ' compared to the curve e from FIG. 2 is slightly offset in the direction of larger carrier values or smaller level values. With this type of carrier control, the carrier value is controlled in the same direction as the level down to a lower minimum level value P 1 (less than Po) .This results in a new break point C at the level value Pi , which deviates from the previous break point B , and the steeper part of the characteristic curve e ' runs now not just along the line OA, for which the modulation level is constantly equal to 100%, but on the characteristic curve section e ' , the modulation level m varies from a modulation level dependent on the offset (compared to e) and the residual carrier value R at C to 100% at A, as is on the basis of the straight line, it can be seen which corresponds to a characteristic curve for a carrier control with a constant degree of modulation of 90%. The offset of the characteristic curve part e ′ with respect to e creates a modulation reserve by means of which brief overmodulation can be prevented in the event of a sudden rise in the level.

F ^! g.4 shows the curve d for possible energy savings E as a function of the residual carrier value R. Here, dif curve Λ shows the energy savings for a specific level curve for a carrier control according to the characteristic curve c of FIG Energieeinsparu! .G represents for the kinked characteristic curve def according to FIG. 2. It is seen that when a carrier leak value of 60% of the maximum Träperwertes Tm instead of by the characteristic curve c possible energy saving of 50% now to the characteristic dcf an energy saving of about 60% (is possible icweils opposite Ampli.udcnmodulation without Deception control according to R - 100% Tm.

In a nutshell and in a simplified manner, a preferred

tes embodiment of the invention so the following less than before and increases only at

characterize: Achievement of larger (depending on the carrier residual value)

In the case of an amplitude-modulated transmitter with a carrier modulation degree, the higher the level, the steeper the signal.

control with residual carrier, the carrier value increases compared to the known carrier control.

Remaining carriers are not linear, as was previously known > With the residual value of the carrier, a further savings

achieved with increasing level starting from the level value.

Zero on, but the carrier value remains from zero The preferred capital case / from c'gegemiher cm Ii g. )

rising level initially constant or only increasing in amounts to approx. 20% of Tm {bet K -.- 6O ¹¹ ;, Tm).

For this purpose I sheet drawings

Claims (2)

Patent claims: 1, amplitude motJuliener transmitter with operating point control of the carrier oscillation (carrier control) between a maximum value (Τψ) and a residual carrier value (R) which occurs in the same direction with the level (P) of the modulation signal, characterized in that means are provided for carrier control according to a characteristic curve (def , d-e'-f) of the carrier value (T) as a function of the level (P), which from the straight line (c, Fig. 1) through the two points carrier residual value (R) at modulation level value zero and maximum carrier value (A) at The maximum permissible modulation level (P _n ) deviates in such a way that, at least in the area of the most frequently occurring level values, these are assigned a smaller carrier value than corresponds to the course of the straight line (C) 2. Transmitter according to claim 1, characterized in that the slope of the characteristic curve (def. D-e'-f) from the smallest in the direction of larger level values