CS214060B1 - Connecting an electronic circuit to a time shift signal - Google Patents

Abstract

The invention belongs to electronics and achieves a large delay or signal prediction. The essence of the invention is that the point consists of a multiplier, a derivative, a signal source, a circuit for determining the polarity of the signal, a relay element, a filter, a circuit for processing the shifted signal, an integration element, a block for generating the magnitude of the time shift of the signal and a high-frequency signal generator. The invention can be used in the electrical engineering field. The actual connection of the subject of the invention is shown in the attached drawing.

Description

(54) Connection of electronic circuit for time shift of signal

The invention belongs to the electronics and achieves a large delay or signal prediction.

The point of the invention is that the point consists of a multiplier member, a derivative member, a signal source, a signal polarity determining circuit, a relay member, a filter, a shifted signal processing circuit, an integrating member, a signal shift amount generating block and a high frequency signal generator.

The invention may be used in the electrical engineering field.

The actual connection of the object of the invention is in the attached drawing.

214 060

214 060

The invention Ba relates to the connection of an electronic circuit to a signal shift from a signal source. The delay and the prediction of the signals are considered.

The hitherto used circuits for obtaining a single signal are formed by memory cells or circuits realizing approximate delay by substitute mathematical expression. Circuit wiring is based on models that work in advance of the real process, principles based on statistical methods, and traffic delay wiring in the operational amplifier.

The connections to create a single signal are complicated, some allow getting only a relatively small delay. Difficulties arise when the demand has created a variable delay and the delay of noisy signals. Leading systems are complex, easy to implement for variable lead timers, etc.

Said drawbacks are eliminated by the circuitry of the signal shifting circuit according to the invention, which consists in that the first input of the multiplication network is connected via a differentiated signal to the first input of the signal source or this input is directly connected to the second derivative output of the signal source. This first output of the multiplier Si is still coupled through the signal polarity circuit to the relay input Si. The first input of this relay Siena is connected to the first output of the signal source, and the second input is connected to the output of the multiplying Siena. The output of the relay Siena is connected both by a filter to the first input of the shift signal processing circuit and by an integration wire to the shift signal processing circuit. The integrated Siena output is connected to the third input of the relay Siena. The Sax shift signal size generation block is connected to the second input and the high frequency signal generator is connected to the third input of the multiplier Sien.

The circuitry of the electronic circuit for generating the Saxon signal shift is realized in such a way that a derivative of the signal to be attained by the Saxon shift is obtained from the derivative Siena or the signal source. The magnitude of the signal derivation and the magnitude of the desired Saxon offset generated by the Saxon offset size generation block are modulated in the multiplier by the amplitude of the symmetric signal from the high frequency signal generator. The output signal of the multiplier Siena is based on the signal to be moved and connected to the input of the relay Siena. The Relay Hall with Integral Dream forms a heline filter chamber. Because of the increasing signal, the symmetrical characteristic of the relay Siena, and the symmetrical output signal from the high frequency generator, an integer Siena output signal is generated by integrating the Siena output signal as an epic envelope of the control signal set and the multiplier Si signal. When the polarity of the derivative signal is changed, the characteristics of the relay Siena become asymmetric and thus the output signal of the integration Siena begins to follow the upper envelope of the signal set.

By connecting an electronic circuit, a simple circuit achieves a large signal delay or prediction. The signal shifting of the signal may be variable, the input signal may contain a parasitic component, the output signal derivative may be obtained and the circuits may be cascaded.

The attached drawing shows the wiring of an electronic circuit to the Sax shift signal.

214 060

The wiring itself consists of a signal source 1, which is connected to a multiplier 5 via a derivative Si 2. A time shift amount generating block 3 and a high-frequency signal generator 4 are connected to the multiplier 5. the signal from the signal source 1 and the output of the integrator 7. The signal polarity determining circuit 8 is connected from the output of the derivative member 2 and connected to the adjustment input of the relay member 6. This relay member 6 is connected via the integrator 7 and filter 9 time shift signal processing circuit 10.

The activity of the circuit is similar in generating a signal that is ahead of the control signal. In this case, for the rising signal, the characteristic of the relay member is asymmetric and for the decreasing symmetric.

Claims (1)

OBJECT OF THE INVENTION The circuit of the electronic time shift signal circuit is characterized in that the first input of the multiplier (5) is coupled via the derivative member (2) to the first input of the signal source (1) and / or directly connected to the second derivative output of the signal source (1). and is further connected via a signal polarity determining circuit (8) to the setting input of the relay member (6), the first input of which is connected to the first output of the signal source (1) and the second input of which is connected to the output of the multiplier (5) the relay member (6) is connected via a filter (9) to the first input of the shifted signal processing circuit (10) and to the second member of the shifted signal processing circuit (7) via an integrating member (7), the output of the integrating member (7) being coupled to the third input of the relay member (6), while the signal offset size generation block (3) is connected to the second input of the multiplier member (5) and the generator or the high frequency signal (4) is connected to the third input of the multiplier (5).