SU902204A1 - Frequency-modulated signal shaper - Google Patents

Description

(54) FORMER OF FREQUENCY-L MODIFIED

one

The invention relates to devices for generating frequency-modulated signals and can be used in electronically tuned frequency response generators made of, for example, reverse-wave tubes, mittrons, Gunn diodes.

A shaper of frequency-modulated signals is known, comprising a DC voltage source connected in series across a common bus, a backward-wave lamp (BOW) and a switch unit, as well as a current-discharge pulse generator, the output of which is connected to a BOV control electrode one.

However, the known driver of frequency-modulated signals has a low installation accuracy and stability of the average frequency.

The purpose of the invention is to increase the accuracy of the installation and the stability of the average frequency.

For this, a frequency-modulated signal forwarder containing DC-connected in series DC voltage signals

Claims (1)

A common busbar, BOB and a switch block, as well as a current discharge pulse generator, the output of which is connected to the BWO control electrode, are in series connected a step voltage driver and a counting device, one output of which is connected to the control input of the current reset pulse generator, and the other outputs are connected respectively to the control inputs of the switch unit, as well as a direct current amplifier (ULT), made on a dynamic-load electron tube, which represents a circuit of series-connected transistors and is connected between a constant-voltage source and an input of a switch unit, while the cathode of an ULT electron tube is connected directly to another output of a stepped voltage driver and through a capacitor to a connection point of an UL-U lamp of an ultravoltage ULT with the input of the switch unit, and the grid of the ULT electron tube is connected through the corresponding resistors to the VOD anode and to the common core. FIG. 1 shows a structural electrical circuit of the proposed shaper; FIG. 2 - time diagrams that show his work. The frequency modulated waveform shaper contains a 1 constant voltage source 1, connected to a common spike, a DC amplifier 2, made on the electron tube 3 with a dynamic load, which is a circuit of series-connected transistors 4 and 5 (resistors 6 and 7, providing the operation mode of the transistors at a constant current), the switch unit 8, consisting of (P - 1) identical cells (n is an integer), each of which consists of a switching transistor 9, the switch 10 itself and the stabilizing d for example, a zener diode 11, a backward wave (BOW) lamp 12, a generator of 13 current discharge pulses, a scaler 14, a stepped voltage driver 15, resistors 16 and 17, and a capacitor 18. To obtain the required BWL 12 frequency setting accuracy, N discrete voltage levels, the accuracy of setting the BWO frequency is equal to D, where S is the average steepness of the BWO 12 frequency tuning, AU is about the tuning voltage; N is the number of discrete voltage levels or the number of first switches. The required number of discrete levels can exceed 10 - Y. The number of cells (n-1) of the switch block 8 and the number of voltage levels on the driver of the 15-step voltage generator are chosen based on the required number of discrete frequencies of BWL 12, according to the expression. N 2 p. In the proposed shaper, the number of switches of large discrete voltage levels is (n − 1), since one large discrete level AUo is additionally formed at the load of the amplifying lamp 3. The shaper of frequency-modulated signals works as follows. In the initial state, in the absence of external control pulses, the current of the BWO 12 creates a voltage drop AU and the total voltage AU AUo X (n -1) in each Zener diode 11 of the block 8 switches. (Fig. 2f, the linear-step voltage is shown on the VOV control electrode). On admission, ia input of the step voltage generator 15 and the control pulses shown in FIG. 2a, a circuit-step voltage (Fig. 26) is realized at the output of the step voltage generator 15 with a number of voltage samples 2 with the possibility of stopping the voltage at any of the samples when removing control pulses. After passing 2 voltages in the stepped voltage shaper 15, the voltage on the dynamic load changes from AUo to the minimum. During the reverse voltage in the step voltage former 15, the control pulses of the switch block 8 are fed to its other output, and the counting device 14 is used to selectively connect the control pulses to the switches of the switch block 8. P-after the passage of the first cycle of formation of a stepped voltage, the calculating device 14 includes the first cell of the switch unit 8 (Fig. 2e shows the control pulse of the first cell). After the second cycle of step voltage formation, the second cell of switch unit 8 is turned on (in Fig. 2d the control pulse of the second cell is shown), and after (n-1) cycle the last cell of switch unit 8 is turned on (in Fig. 2d the control pulse of the last cell is shown) . Thus, at 2 levels on dynamic load 2 and (n - 1) cells in switch block 8, the total number of switchings N (n - 1) 2 + 2 is obtained. Resistors 16 and 17 form a negative feedback circuit that stabilizes the voltage on control electrode BOV 12 in the conditions of temporal and temperature instability. After successive shorting of the zener diodes 11 by the switches 10 and the processing of an additional discrete level I, the scaling device. restored to baseline conditions; at the end of the current discharge pulse, the oscillation frequency of the BWO 12 reaches the initial minimum value. The device returns to its original state and with further receipt of control pulses in the 15-step voltage driver, a new cycle of its adjustment begins. In the diagram of FIG. 2c shows the total output voltage at the BOVOE control electrode 12. The presence of a capacitor 18 leads to the differentiation of the amplified stepped voltage and the supply of selected short pulses to the cathode of the electron tube 3 to ensure the fastest possible closing of the DCF. Since the voltages at the anode and cathode of the electron tube are in phase, the introduction of positive feedback leads to an increase in the speed of the transition from discrete to discrete output voltage. Thus, in the proposed shaper frequency-modulated signals increased the accuracy of the installation stability of the average frequency. Claims of the Invention A frequency-modulated signal generator comprising a DC voltage source connected in series but connected to a common voltage, a backward wave lamp (BOW) and a switch unit, as well as a current-release pulse generator whose output is connected to a control electrode . m BOV, characterized in that, in order to improve the installation accuracy and stability of the average frequency, sequentially connected step voltage shaper and a scaler are introduced into it, one the stroke of which is connected to the control input of the generator of current-reset pulses, and the other outputs are connected respectively to the control inputs of the switch unit, as well as a direct current amplifier (UPT), made on a dynamic-load electron tube, which is a circuit connected transistors and is connected between the source of direct voltage and the input of the switch unit, while the cathode of the UFT electron tube is connected directly to another output of the step voltage generator In addition, through a capacitor, to the point of connection of the dynamic load of the UPT electron tube with the input of the switch unit, and the grid of the UPT electron tube is connected through the corresponding resistors to the VLO anode and to the common busbar. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 229613, cl. H 03 C 3/30 ,. 1966.  Control Impulses -1- Figure 1 but III III III 11II Mi 2 Discrete 08 17 8 P 17 Jt 7 -i four% -. one : : H