SU985966A1 - Frequency-shift keying device - Google Patents

Description

(5) FREQUENCY MANIPULATOR

The invention relates to a data transmission technique and can be used in communication systems for transmitting digital information using frequency shift keying.

A frequency maT + amplifier is known, which contains two shock excitation generators and a synchronizer, the first output of which is connected to the control input of the first electronic key tl) A disadvantage of the known frequency manipulator is that it does not allow generating a signal with a multiplication index 0.5 and also not fast enough.

The purpose of the invention is the formation of signals with a manipulation index of a multiple of 0.5 and an increase in the speed of the manipulator.

To achieve this goal, a second electronic key, adder, pulse edge selector and serially connected reference generator: 5tor, first trigger are entered into a known frequency manipulator containing two shock excitation generators and a C11 synchronizer, the first output of which is connected to the control input of the first electronic switch. the third electronic key, the second trigger and phase switch, to the second input of which the output of the adder is connected, the inputs of which are connected to the outputs of the first and second electronic key minutes, signal inputs of which are respectively connected to the outputs of the first and second generators of shock excitation to

Claims (2)

15 inputs of which are connected to the second output of the first trigger, the input of which is connected to the input of the synchronizer, the second output of which is connected to the control 2Q of the second electronic key and to the input of the pulse edge selector, the output of which is connected to the second input of the third electronic key. 398. FIG. 1 is a block diagram of a frequency manipulator; in fig. 2 - time diagrams that show his work. The frequency manipulator contains a reference generator 1, a first trigger 2 a first generator 3 of shock excitation, a second generator k of shock excitation, a synchronizer 5, a first electronic switch 6, a second electronic switch 7, an adder 8, a phase switch 9, a selector of 10 pulses, a third electronic switch 11 and the second trigger 12, the Frequency Manipulator operates in the following manner. The signal from the output of the reference oscillator, 1 (Fig. 2a), is fed to the input of the first trigger 2, the output of which produces a pulse signal with a duty cycle of two (Fig. 2d). The tipping of the first trigger 2 occurs at the leading edge of a logic level 1 pulse from the output of the reference generator 1. The pulses from the second output of the first trigger 2 arrive at the inputs of the generator 3 and k of shock excitation and synchronize them so that at the moment of arrival of the pulses the generation starts from the zero phase simultaneously for both shock and excitation generators (Figures 2-6, t, moments t, tj, ty, etc.). To obtain a manipulation index of 0.5, the frequencies of the signals from the generator 3 and j of shock excitation are set to be multiples of the signal from the output of the first trigger 2, and the difference between the frequencies is equal to the frequency of the signal from the output of the first trigger 2. In this case, the instantaneous phase difference between signals of generators 3 and t of shock excitation at the moment of transition of the signal at the output of the first trigger 2 from a high to a low level equal. lOoO / j ... O - ...-... , t by 180 d.). t6 and T. In the synchronizer 5, the information signal (fig. 2d) is synchronized with the pulses of the reference generator 1, and the information output is generated at the first output of the synchronizer 5, the moments of which change from one level to another coincide with the moments of the arrival of pulses from the reference generator 1 and, therefore, with the moments of tipping the first trigger 2. At the second output of synchronizer 5, an inverse synchronous information signal is formed. The pulse edge selector 10 generates short level 1 logic pulses, the instants of which coincide with the moments of changing the information signal from one level to another (Fig. 21, moments t The first electronic key transmits the signal of the first generator 3 of the percussion generator to the adder 8) When a high level of information signal at the first output of the synchronizer output of the first electronic key 6, radio pulses are formed with a carrier frequency equal to the frequency of the first generator 3 of the shock excitation (Fig. 2d, PS, intervals t, etc.). At these same time intervals, the output of the second electronic key 7 maintains a logic level O (Fig. 2, intervals), because the information signal is low The second electronic key 7 is closed at these intervals from the second output of the synchronizer 5. The signal of the second shock excitation generator t passes to the output of the second electronic key 7 at a high information signal level at the second output of the synchronizer 5, i.e. at a low signal level at the first output ( FIG. 2, intervals t -, - ta. etc.). -. V4 The signals from the outputs of both electronic switches 6 and 7 are fed to an adder 8, at the output of which a frequency-manipulated signal is formed, having phase discontinuities at the time the information signal changes from one level to another, coinciding with the signal changes at the output of the first trigger 2 from high to low (fig. 2tt, tf, moments t ,, t. o As the signal input of the third electronic key 11 receives pulses from the selector of 10 pulses, coinciding with the instants of the signal change from one level to another , and the control input receives pulses from the first output of the first flip-flop 2, then the output of the third electronic key 11 passes pulses of the selector 10 fronts of pulses, which coincide with the instants of breaking the phase of the signal at the output of the adder 8, t, t The pulses from the output of the third electronic key 11 are fed to the input of the second trigger 12, the overturning of which occurs along the leading edge of the pulse of the level of the logical unit (FIG. 2A, moments t, t, tg). The signal from the output of the adder 8 (FIG. 2.) and the signal from the output of the second trigger 12, (FIG. 2A) go to the first and second inputs of the phase switch 9- If the signal on the second trigger of the second trigger 12 has a high level (logic level then the signal from the output of the adder 8 through the phase switch 9 passes with the same phase (Fig. 2A, and, M :, the interval ti t, if the signal at the output of the second trigger 12 has a low level (logical level Q), then the signal from the output yes adder 8 through phase switch 9 passes with a shift by (FIG, 2n, and, ln, interval). Since the phase change s at 180o occurs at times when the signal at the output of the adder 8 has a phase jump of 180, then an additional phase switching of 180 in phase switch 9 leads to the formation of a frequency-manipulated signal at the output without phase discontinuities (FIG. 2l). The technical and economic effect of the image is that the frequency manipulator possesses a short transient time from one frequency to another, since switching from one frequency to another without a phase break does not require tightening the frequency of one shock generator. an excitation signal generator of another shock excitation, and determines a switching time .s ELECTRON keys 6, 7 and 9, the phase switch, the switching time which is determined by the speed of the elements used. In this case, the quality factor of oscillatory systems of a generator of shock excitation tori can be selected sufficiently high. In addition, the frequency manipulator allows the formation of a frequency-manipulated one. the signal without phase break with manipulation indices that are multiples of 0.5 (i.e., 0.5; 1; 1.5, etc.). The invention has a frequency manipulator comprising two shock excitation generators and a synchronizer, the first output of which is connected to the control input of the first electronic key, characterized in that, in order to generate signals with a manipulation index of a multiple of 0.5, and speed increase, A second electronic key, an adder, a pulse front selector and a successively connected reference generator, the first trigger, the third electronic key, the second trigger and the phase switch, to the second input of which The output of the adder is connected, the inputs of which are connected to the outputs of the first and second electronic switches, the signal inputs of which are connected respectively to the outputs of the first and second shock excitation generators, to the inputs of which a second output of the first trigger is connected, the input of which is connected to the synchronizer input, the second output of which is connected control input of the second electronic key and the input of the pulse edge selector, the output of which is connected to the second input of the third electronic key. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 352364, Kh, H 03 C 3/00, 1970 (prototype). 1