CH622390A5 - Pulse width modulation circuit - Google Patents

Description

The invention relates to a pulse line modulation circuit according to the preamble of claim 1. Figures 1 and 2 show through the German magazine: Nachrichten Elektronik 10 (1976), pp. 234-236 known types of such modulation circuits. In the figures, N means the network, PA the pulse processing, PS the pulse control, PR the pulse tube, FD the freewheeling diode, SS the voice coil, SR the transmission end tube. In the first circuit (FIG. 1), all electrodes of the transmission end tube SR must be at a high potential. In the second circuit, the cathode of SR is connected to ground, whereby the interference effects of the electrode capacitances which can be felt in the first circuit are avoided. Apart from that, the two known circuits have serious shortcomings. 1 has to work with the cathodes of the HF tubes on a mixed low-frequency direct voltage potential, which is difficult to achieve with KW-AII band transmitters and with MW and LW transmitters. 2, this problem is avoided consistently, but on the other hand there are difficulties with resonances in the coupled coil SS and the coupling capacitor. As a result of undesirable resonances, pulse deformations can occur, which immediately leads to harmonic distortion problems and a loss in efficiency. The pulse repetition frequency must be as high as possible, especially with regard to distortion or intermodulation distortion. In this regard, it is noteworthy that the circuit shown in FIG. 1 operates with a pulse repetition frequency of 75 kHz, whereas the circuit according to FIG. 2 only works with approximately 50 kHz. As a theoretical analysis shows, a pulse repetition frequency of 50 kHz is already at the lower limit with regard to the intermodulation products.

The invention has for its object to improve a pulse duration modulation circuit of the type described above and to design such that a high pulse repetition frequency can be used and that the RF stages work with the cathodes at ground potential.

The object is achieved in connection with the features of the preamble according to the characterizing part of patent claim 1. Further developments of the invention are described in the dependent claims.

The invention will now be explained in more detail with reference to FIGS. 3-9. FIGS. 3 and 4 show the characteristic features of the proposed basic circuit using two exemplary embodiments. The circuit uses a simple pulse or voice coil SS with one winding end at ground potential, which also has advantages for the construction and placement of the coil.

The pulse processor PA, the heater and the bias rectifier for the control and screen grids of the pulse tube PR must be connected to their cathode potential, which corresponds to the known prior art. The free-wheeling diode FD can be problematic insofar as the heating transformer must be at a different potential than the heating of the pulse tube PR when using a heated tube diode. This does not pose any fundamental difficulties or physical problems; In the end, this is a question of transformer insulation and therefore a question of price.

The great advantage of the circuit proposed according to the invention is that a simple voice coil SS (without a secondary coil) is connected to ground with one end of its winding and this point is simultaneously connected to the cathode of the HF stage; this offers the possibility of using the highest possible pulse repetition frequency while at the same time restricting the distortion factor. A relatively high modulation frequency can also advantageously be used. Due to its properties, the proposed circuit can also be used as a modulator for medium and long-wave transmitters.

In FIGS. 3 and 4, GR also means the line rectifier, Mod the modulation signal, TF the low-pass filter, Cs a stray capacitance, N the line, UaREF the anode DC voltage reference, HF the high-frequency stage, FDr, FD1, FD2 filter chokes, FK the filter capacitor.

A feature of a PDM (pulse duration modulation) system is that one can do without an adjustable high-voltage rectifier. With the pulse system described below, the DC voltage can also be continuously regulated, which is particularly important for KW operation.

Another feature is that you can access the

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"Crowbar" renounce the known shutdown measure i.e. the one binary state, while otherwise the swell can The pulse switch (blocking the positive trigger pulses) provides a zero output signal. This creates the anode voltage immediately to zero. If there is a flashover in the pulse at a fixed threshold value (voltage at the upper input) on the tube, then high-voltage switch 5, not shown, must be used by a detector that uses the output of the threshold value switch 21.3 square-wave pulses.

to be triggered. The following method can advantageously be used here. These square-wave pulses are now used for the differentiation stage; When the negative edges are fed to the pulse 21.4 (Fig.5,6). From the rising flank of the right tube anode, tripping is carried out immediately, corner impulse this differentiation stage forms a positive Na. When implementing the circuit according to FIG. 3, delimpuls, which is then polarized accordingly, must not prevent the LF signals through the rectified diode and via the control line T23 to the ter GR in the network. With the normal Fil control input the pulse tube arrives. In the case of the resulting ter-elements FDr (filter choke) and FK (filter capacitor) flank of the square-wave pulse, the differentiating stage 21.4 delivers the LF signals via the capacitance between seconds and a negative needle pulse, which is then fed into the network via a second, non-dar- and primary winding of the mains transformer . A diode, shown this time with a different polarity, on a non-Darge-static screen alone, as shown in FIG. 4 and with a reversing element provided with StS 15 (normal transistor stage in the emitter scarf, may not be effective without additional measures) reached. Full protection is provided from the output of this inverter. 4 brings a control line T22 to the control input of the pulse tube. Division of the filter choke FDr into two in FIG

Partial chokes Fdrl and FDr2, each set to one pole of the rectifier output line. If the transmitter power is changed ters GR are connected. This makes it possible to achieve a significant 20, so the present high-power transmitter needs through-loss. If particularly resistant arrangement occurs only the DC voltage U = (FIGS. 5 and 6) ent frequency components can be changed accordingly from the ones shown in FIG. 4, since these have a linear function points A and B against mass capacitances or suction circuits of the DC voltage component Switch on U0 of the modulation signal SK. The filter capacitor FK remains the same. is. It is advisable to set U0 with a low pass filter: s control loop is used to screen the pulsed signal, since this method is the most accurate. TF, consisting of Ci, L and C2 (naturally, a small other low-pass circuit can also be used for this, as shown in FIG. 5, see C3 in FIG. 3 extension.

and 4). Using an auxiliary DC voltage + UB and a potentiometer

The solution according to FIG. 4 is hardly more complex than the meter pot, the setpoint for the DC voltage component is

Known solution according to FIG. 2. Instead of a filter choke FDr 30 element U0 at the negating input of the comparison circuit, two smaller ones are required, on the other hand 21.7 is sufficient. Since we are not working with a few kV, a simple pulse coil SS (without a secondary coil and therefore with a scale factor k must be taken into account; this results in “fik-less problems”), which even directly relates to the mass vertical »setpoint U0soii • k. Reduced by the same factor k is bound, which saves space. The freewheeling diode FD arrives at the non-inverting input of the comparison can be a tube diode (heating transformer with high insulation circuit 21.7, the DC voltage component U0-k The component above is the low-pass filter in the negative feedback branch GK

As can be seen from FIG. 3, the pulse processing system 21.6 (FIG. 5) is switched on. As a comparison circuit in stem PA can be connected to ground potential. Over two routes, the z. B. known manner expediently used as a differential amplifier through RF paths, through optical fibers or through a pulse-40 operational amplifier. This transformer with high insulation quality between primary and secondary windings, which are located at its two inputs, is known to be able to generate voltages in the form of:

of the PDM signal, the signals formed on the flanks of the PDM signal are transmitted - U = = (U0 • k) - (Uos0ii • k) or th, opposite-polarized pulse peaks over each of the 45

said two routes. U = = (U0-Uos0ii) • k.

The details of the preparation will now be explained with reference to FIGS. 5 and 6. To illustrate the rule, assume that with

The pulse conditioning PA, FIGS. 3 and 4, or the control device using the potentiometer Pot a reduction of the DC-21 in FIGS. 5 and 6, consists of circuit voltage% component U0 (and thus a power reduction) that is known per se 5 and 6 as blocks (in order to achieve this) (U0soii can also be specified by the transmitter control as the control value (manipulated variable) appearing at the outputs T22 and T23).

Signals UT22 (positive flank) and UT23 (negative flank) better If Uosoii k is kept constant, it can be traced as a result of the action, the corresponding voltage-timing of the control loop ensures that U0 constant diagrams for the voltages on the individual Connection 55 remains.

lines drawn in. So now with a changed DC voltage component U0

The sine generator 21.1 supplies a pulse at an output, which once the degree of modulation has been set is maintained, becomes voltage with a repetition frequency that corresponds to the desired modulation signal Umod via a multiplier 21.5 pulse frequency. (Fig. 5) passed. This changes its gain proportionally

The modulation signal voltage Um0d to be amplified becomes 60 to the DC voltage applied to its control gear via a coupling capacitor C of a DC voltage U = U = • m.

overlaid. The resulting voltage Umod + U = is present in order to avoid repercussions from the output of the multiplication input (shown in FIG. 5 as the lower input) of the 21.5 on its control input, is in the threshold switch 21.3. The threshold switch is turned on control line the setting element 21.8. This entai binary component is formed, i.e., said lower 65 holds a low pass filter to ensure that only the DC input carries the reference potential Umod + U =, and always then, voltage U = comes into effect. In addition, if the voltage at the other (upper) input exceeds the reference one potentiometer for setting the said factor m potential, the low pass filter is followed by the signal L at the output, with which the desired modulation

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degree m * is adjustable. According to a second method, the modulation signal

In the PS unit (pulse control) FIG. 3, PDM (pulse duration with subsequent voice coil SS 'and low-pass filter TP') are again formed from the taps on the pulse coil SS (FIGS. 8a and b) and positive and negative trigger pulses.

modulated) pulses generated, which generates the control grid of the pulse tube together with screen rectifier GR '. However, it must

Control PR. 5 here because of the high screen decoupling capacitance Cg2

With pulse duration modulation circuits, it is often desirable to modulate the internal resistance of the circuit for the LF signals very much with the screen grid of the HF end tube. To be low, which may be difficult with a known method, using a small, separate one.

rate modulation transformer, which is quite expensive. A third method is to modulate the shield-lig. Another known method uses a series io grid via a separate tube or power transistor resistor in the shield grid circuit; but here the distortion amplifier M (Fig. 9). But you have to make sure that the two-factor is increased. see the anode modulation and the screen grid module

The circuit proposed according to the invention does not allow any voltage differences to exist. In order to avoid the disadvantages of the known methods and to avoid such differences, two variants are shown in FIG.

a simple and inexpensive screen grating co-modulation is stated, according to which the modulated signal via real capacitive. According to a first method (Fig. 7) one can on or ohmic voltage divider from the anode modulator

Output of the pulse filter, where the capacitor C2 is located, is fed to the screen grid modulator.

install a capacitive voltage divider. Here, e.g.

C2 ~ 5.9 nF and the screen grid capacitance Cg2 ~ 60 nF. This is achieved by regulating the anode voltage in a continuously controllable manner with the circuit of FIG. 9. For the supply of the 20 ben, the screen rectifier GR 'u. A choke may also have to be installed. The input can be continuously regulated, specifically via a control input Pu, and is controlled directly at the terminals of the capacitor Ci in gang Reg. This Reg signal controls the Fig. 3.4 connected at the same time. Anode voltage (U0 Fig. 5; U = Fig. 6).

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4 sheets of drawings

Claims (10)

622390 PATENT CLAIMS 1.Pulse duration modulation circuit with a pulse conditioning (PA) of a modulator tube (PR) controlled on the grid side by pulse duration signals, which on the anode side via a series connection of a pulse coil (SS), a high-frequency tube output stage (HF) and an inductance (L) of a low-pass filter (TF) with the positive voltage output (A) of a mains rectifier (GR) is connected, the anode of this modulator tube being connected via an outdoor diode (FD) to this positive voltage output of the mains rectifier (GR), characterized in that the one end of the pulse coil (SS ) connected cathode of the anode-modulated high-frequency tube output stage (HF) is grounded and the cathode of the modulator tube (PR) is connected to the negative voltage output (B) of the mains rectifier (GR). 2. Modulation circuit according to claim 1, characterized in that two partial filter chokes (FDrl, FDr2) are used for screening, which are connected between an output of the rectifier (GR) and the terminals of a filter capacitor (FK). 3. Modulation circuit according to claim 2, characterized by suction circuits (SK) which are connected between the outputs of the rectifier (GR) and ground. 4. Modulation circuit according to claim 2, characterized by capacitances (C) which are connected between the outputs of the rectifier (GR) and ground. 5. Modulation circuit according to one of claims 1 to 4, characterized in that the shield grid of the RF end tube is also modulated. 6. Modulation circuit according to claim 5, characterized in that a capacitive voltage divider is arranged at the output of the low-pass filter (TP), the tap of which is connected to the screen grid of the HF end tube (HF). 7. Modulation circuit according to claim 5, characterized in that the modulation signal for the screen grid of the HF end tube by means of a tap on the pulse coil (SS) (Fig. 8), subsequent voice coil (SS '), low-pass filter (TP') and screen grid rectifier ( GR ') is generated. 8. modulation circuit according to claim 5, characterized by a modulation of the screen grid via a separate tube or power transistor amplifier (M, Fig. 9). 9. Modulation circuit according to claim 8, characterized in that the modulated signal via capacitive voltage dividers from the anode modulator is fed to the screen grid modulator. 10. Modulation circuit according to claim 8, characterized in that the modulated signal is supplied to the screen grid modulator from the anode modulator via ohmic voltage dividers.