SU853787A1 - Pulse shaper - Google Patents

Description

The invention relates to a pulse technique and can be used in radio engineering, radar and sonar.

A device containing a delay line, a coincidence element and an OR element is known, and the outputs of the coincidence element and the OR element are connected to the inputs of the power amplifier £ 1].

However, this device is notable for a small accuracy in the formation of a pause between the moments when the transistors are turned on due to the use of an analog delay line and does not allow when the load of the power amplifier 15 is not fully compensated and is reactive; work with phase-shift keyed signals.

, The closest technical solution to this invention is a pulse shaper containing a trigger, the outputs of which are connected to the first inputs of the output matching elements which are outputs of the pulse shaper * 5].

The disadvantage of this device is that it does not allow to receive phase-shifting signals at the output. thirty

The aim of the invention is the expansion of functionality while increasing reliability.

This goal is achieved by the fact that in the pulse shaper containing the output trigger, the direct and inverse outputs of which are connected to the first inputs of two coincidence elements, the outputs of which are the outputs of the pulse shaper, an annular shift register, a shaper of the inhibit signals and a manipulator consisting of a trigger are introduced, two inverters and two additional matching elements, the first inputs of which are combined and connected to the output of the trigger, the second inputs are combined and connected to the first input of the ring of the moving register, with the input rh and through the first inverter connected to the counting input of the trigger, the third inputs of the additional matching elements respectively through the second inverter and directly connected to the bus of the manipulating signal and to the input of the driver of the inhibit signals, the output of which is connected to the second inputs of the matching elements, the third inputs ; obe3 dineny and which are connected to the counting input of the flip-flop output and a yield of single, annular th bits of the shift register, the second input of which is connected to the bus of the periodic sequence of pulses, the inputs _r setting and resetting of the flip-flop ^J vyhodno- connected to the outputs of additional elements coincidences "

In FIG. 1 is a functional diagram of a pulse shaper / in FIG. 2 - time charts characterizing its operation.

The device comprises an output trigger 1, coincidence elements 2,3, an annular shift register 4, a shaper of inhibit signals 5, a manipulator 6, consisting of an inverter 7, a trigger 8, coincidence elements 9 and 10, an inverter 11.

The bus 12 of the annular register 4 serves for supplying a periodic sequence of advance pulses, and the input bus 13 for a periodic signal with a frequency two times higher than the average frequency of the output signal. Bus 14 serves for supplying a manipulating signal 25. Direct and inverted output of the output latch 1 connected to first inputs of coincidence elements 2 and 3. The second inputs of the coincidence elements 2 and 3 together, are connected to the counting input of latch 1 ¹⁵⁰ and sub shreds to an output shift register 4. Inputs and installation. reset ”of the output trigger 1 is connected to the outputs of the matching elements: 3 and 10 of the manipulator 6. The first inputs of the matching elements 9 and 10 are combined and connected to the output of the trigger 8 of the manipulator b, the counting input of which through the inverter 7 is connected to the bus 13 of the imager 40 pulses connected to the input. forced installation of an annular shift register and with the second inputs of the matching elements 9 and 10. The third inputs of the matching elements 9. and 10, respectively, through the inverter 11 and are directly connected to the input of the Shaper with latter is present prohibition 5 and the bus 14 PFN.

The pulse generator operates as follows. ‘'

The bus 12 receives a continuous periodic sequence of pulses with a frequency of F _T. A continuous, periodic sequence of pulses is fed to bus 13, the duration of which is equal to one frequency period F _T , and the frequency is F _T ) m (Fig. 2a), where m is an integer. Bus 14 is designed to supply a manipulating signal (_Fig. 2 V), and 60 it is assumed that the highest signal frequency on bus 14 is much less than the frequency F _T / m.

The annular shift register 4 has m bits and for each pulse 65 on the bus 13 it is forcibly set to a state characterized by the presence of a low potential on its η-first bits and the presence of a high potential on the remaining m-n bits. The initial state of triggers 1 and 8 is arbitrary. Consider the operation of the device from time t (figure 2) coinciding with the leading edge of one of the pulses on bus 13 and characterized by the presence of a high potential on bus 14. We assume that at time t, trigger 8 (Fig. 26) is in a single state . Then, at the inputs of coincidence element 9, there are potentials allowing the passage of a pulse from the bus to its output

13. The signal from the output of coincidence element 9 is fed to the input of the installation of trigger 1 and sets it to a single state (Fig. 2e). On the back Front of the pulse from the bus 13, the trigger 8 is switched and the signal passing through the coincidence element 9 is stopped (1 in Fig. 2d). By the signal from the output of coincidence element 9, trigger 1 is brought into a state that coincides with the state of trigger 8 at the moment the signal arrives on the bus

13. The next pulse from the bus 13 does not affect the trigger 1, since the coincidence element 9 is closed by a low potential from the output of the trigger 8, and the coincidence element 10 is closed by a low potential from the output of the inverter 11, the input of which supplies a high potential from the bus 14. Thus Thus, at the output of coincidence element 9, a sequence of pulses is formed, the duration of which, like the duration of the pulses on bus 13, is equal to one frequency period F _r , and the repetition rate is half as much. According to the clock signals supplied to the register from the bus 12, the state recorded in on 'is advanced. the initial moment of time according to the signal from the bus 13. At the outputs of register 4, signals having a low level during n periods of frequency F _T and a high level during m-π periods of frequency F _r appear sequentially (FIG. 2e):

In the event that trigger 1 is connected to the output of the Ν-ΓΟ discharge of the shift register 4, the moment of its switching is shifted by N clock cycles F _T relative to the pulse on bus 12, the state of the output of coincidence element 2 (Fig. ^ G) is determined starting from time t ,, when the state of trigger 1 is determined. If N 7 η, high potentials are at the inputs of coincidence element 2 and a high potential is also at its output. This state is maintained until a low signal level arrives from the output of register 4. Then, coincidence element 2 is turned off (in Fig. 2 a,) and the formation of a pause begins between turning off coincidence element 2 and turning off coincidence element 3.

The pause duration is determined by the number of β-bits of register 4, into which low voltage levels were recorded by the signal on bus 13. After passing from the start of the formation of a pause η frequency periods, a high potential appears at the counting input of trigger 1 and at its inputs of coincidence elements 2 and | 3, switching trigger 1. The signal formation at the output of coincidence element 3 begins. The duration of the output signal is mn frequency periods F _T. The signal from the output of coincidence element 3 is terminated in the same way as in case 15 with the coincidence element 2 when a low potential appears at the N-th output of the register (c in Fig. 2 ^).

Then, after a pause of η clocks, signal formation begins with output 20 of match element 2 (in Fig. 2g). The duration of the signal from coincidence element 2 is also equal to mn clocks E ^ .. Thus, at the outputs of coincidence elements 2 and 3, periodic signals are generated, the duration of which is equal to mn clocks F _T and separated by η clock cycles F _T (Fig. 2g, o). The phase of the trigger 1 signal, and hence the output signal of the power amplifier obtained after summing the signals from the outputs of coincidence elements 2 and 3, differs from the phase of the signal from trigger 8, conventionally assumed to be zero, by N periods of the clock frequency E ^. The processes that cause the formation of signals from the outputs of coincidence elements 2 and 3 are periodically repeated, and random failures in shift register 4 and in output 40 of trigger 1 no later than after a period of the output signal are corrected for signals on bus 13.

The above processes are repeated until the potential changes on the 45 bus 14 from a high to a low level (tg in Fig. 2B). At the time the potential changes on bus 14, the inhibit signal generator 5 starts up, the output of which is supplied with a low jq voltage level, which prohibits the signals from passing through coincidence elements 2 and 3. The duration of the inhibit signal is chosen so that transients in the load connected to the output managed to end, but not less than one period of the output signal. Shift register 4 and trigger 8 continue to work as before, but the coincidence element is now locked and the element coincides. 60 ny 10 is open (moment 2 in Fig. 2d). The output of the coincidence element 10 is connected to the input reset the output trigger 1, therefore, the first after changing the potential on the bus 14 pulse 65 coming to the bus 13, the output trigger 1 is reset (t _b in Fig. 2d, d). Thus, the output trigger 1 is set to the opposite state of the trigger 8 at the moment of the pulse arrival on the bus 13. The start of the inhibit signal generator 5 also occurs when the signal on the bus 14 goes from low to high. After the termination of the inhibit signal, the pulse shaper comes into a state characterized by the formation of an output signal, the phase of which corresponds to the supply of installation signals from the output of the coincidence element 9.

Thus, the sequential inclusion of coincidence elements 9 and 10 depending on the state of the signal on bus 14 allows phase manipulation, moreover, directly in the output trigger 1, the body and the module are formed.

The inclusion in the circuit of the device of the shaper of the inhibit signal 5 allows, with the selected method of phase manipulation, to avoid voltage surges in the transistor output stage that occur during phase manipulation. In the absence of manipulation signals on bus 13, this former operates as a periodic signal generator, protected from through currents through output transistors.

The proposed construction of the pulse shaper circuit is especially useful when developing multi-channel generators with independent adjustment of the phase of the carrier frequency between individual channels. At the same time, for each subsequent channel, it is necessary to additionally introduce the output trigger 1 and coincidence elements 2 and 3. The inhibitor signal generator 5 and manipulator b can be common to all channels. The mutual phase shift of the carrier frequency between the individual channels is determined by connecting the counting inputs of the output triggers and, accordingly, the inputs of the output coincidence elements to the outputs of the corresponding bits of the shift register.

The device can work without supplying a signal to bus 13. To do this, one of the outputs of register 4 through a shortening chain must be connected to the counting input of trigger 8 and, respectively, to the inputs of coincidence elements 9 and 10. In this case, before starting work in the ring shift register 4, it is necessary enter the initial state, which will be periodically repeated.

However, the shaper constructed in this way will have reduced noise immunity, since in the event of a failure in the annular shift register, its state cannot

Ί It can be restored without additional devices specially introduced for this.

Claims (3)

The invention relates to a pulse technique and can be used in radio engineering, radar and sonar. A device containing a delay line, a coincidence element and an OR element is known, and the outputs of the coincidence element and the OR element are connected to the inputs of power amplifier 1. However, this device has a slight accuracy in forming a pause between the switching times of the transistors due to the use of an analog delay line and In the case when the load of the power amplifier is not fully compensated and it is of a reactive nature, it works with phase-shifted signals. The closest technical approach to this invention is a pulse shaper containing a trigger, the outputs of which are connected to the first inputs of the elements the output of which coincides are the outputs of the pulse shaper. 2. A disadvantage of this device is that it does not allow signals to be received at the output of the phases of the manipulator. The aim of the invention is to enhance the functionality while improving reliability. The goal is achieved by the fact that a pulse driver containing an output trigger, the direct and inverse outputs of which are connected to the first inputs of the two matching elements, the outputs of which are the pulse driver shaper, a ring shift register, a ban inhibitor and a manipulator 5 / status are entered trigger of two inverters and two additional elements of coincidence, the first inputs of which are both wired and connected to the trigger output, the second inputs are combined and connected to the first input About the shift of the register, with the input rshny and through the first inverter connected to the counting input of the trigger, the third inputs of additional matching elements, respectively, through the second inverter and directly connected to the bus manipulator signal and the input of the inhibitor signal generator, the output of which is connected to the second input of the elements of the match, the third inputs I of which are connected and connected to the counting input of the output trigger and to the output of one, one of the bits of the ring shift register, the second input of which is connected a periodic pulse train with the set and reset inputs of the output trigger connected to the output / and additional matching elements. FIG. 1 shows the functionality of the pulse driver circuit / in FIG. 2 - timing charts characterizing his work. The device contains an output trigger 1, coincidence elements 2,3, an annular shift register 4, a prohibition signal generator 5, a manipulator 6 consisting of an inverter 7, a trigger 8, coincidence elements 9 and 10, an inverter 11. A bus 12 of an annular register 4 It is used to supply a periodic lasting sequence of forwarding pulses, the input bus 13 is for a periodic signal with a frequency twice the average frequency of the output signal silHHa 14, which serves to give a manipulating signal. The direct and inverse outputs of the output trigger 1 are connected to the first inputs of the elements of the same Lenin 2 and 3. The second inputs of the co-ownership members 2 and 3 are combined, connected with the 5M input of the trigger 1 and connected to the outputs from the outputs shift Inputs setting and The ct5poc register of the output trigger 1 hooked up to the outputs of the coincidence elements: E and 10 of the manipulator 6. The first BXO.DAI elements of coincidence 9 and 10 are integrated together and connected to the output of the trigger 8 of the manipulator 6, the counting input of which through the inverter 7 connected to the uJHEie 13 pulse generator, with d1.shenno11 mandatory to the input shift register setting ring and with the second coincidence ExofiaNW elements 9 and 10, the third input element 9. matcher to 10 respectively through an inverter ieposredstvenno 1 and connected to the signal input of the ban to the bus 5 and the pulse shaper 14. The pulse shaper operates as follows. Bus 12 receives a continuous periodic pulse train at a frequency F. Bus 13 is supplied continuously. The periodicity of the pulse width, whose total frequency is equal to the frequency period FT, and that part is equal to FT / (Fig. 2a), where nn is the whole number. Bus 14 is designed to supply a manipulating signal (Fig. 2c), and it is assumed that the higher frequency signal on bus 14 is much lower than the frequency. An annular shift register 4 has m bits and, according to the calendar, the pulse on ijimie 13 is forcibly set to be characterized by having a low potential on its first bits and having a high-0 potential on the remaining m-n times. The initial state of the triggers 1 and 8 is arbitrary. Consider the operation of the device from the moment of time t (Fig. 2 of a single front of Oipro of impulses on bus 13 and characterized by the presence of a high potential on the bus 14.) At the time ti, the trigger 8 (|) game 2b1 is in the same state Then, at the inputs of the coincidence element 9, there are potentials that allow a pulse from the bus 13 to pass to its output, The signal from the output of the coincidence element 9 arrives at the trigger installation input; 1 k sets it to one state (FIG. 2d). from bus 13 happens per Turning on trigger 8 and passing through the coincidence element 9 is stopped (1 mA of Fig. 2d). HijoM from the output of the coincidence element 9, trigger 1 is brought into the state coinciding with the state of trigger 8 in MO: TLR 13. The next pulse from the bus 13 does not affect the trigger 1, since the coincident element 9 is closed by a low potential from the output of the trigger 8, and the coincidence element 10 is closed by a low potential from the output of the inverter 11, the high potential of which il-; al 14. Thus, on the 3 Day 9 forms a sequence of w /. pulses, the duration of which, like the duration of the pulses on the bus 13, is equal to one; / period of the frequency F ,. and the following frequency is two times less. According to the signals sent to the register from the bus 12, the state recorded in-is progressed. the initial moment of time from the signal from RIGUE 13. At the outputs of register 4, signals that have a low level during periods of F-p frequency and a high level during m-p periods of frequency Rj- appear in series (Fig. 2e) -. In the event that trigger 1 is connected to the output of the Mth digit of the shift register 4, its switching time is shifted by N clock cycles G- relative to the pulse on bus 12, the output state of the coincidence element 2 () is determined starting from time t ,. when the state of the trigger 1 is determined. In the event that N 7 n, at the inputs of the element of coincidence 2 there are high potentials and at its output also a high potential. This state is maintained until a low signal level comes from the output of register 4. Then match 2 is turned off (tr in Fig. 2.d) and a pause is formed between turning off match 2 and turning off match 3. The length of the pause is determined by the number of register bits 4 in which low levels were recorded on the bus 13 signal tension After passing from the moment of the beginning of pause formation to the frequency periods E, a high potential appears on the counting input of trigger 1 and its inputs of elements of coincidence 2 and P. The triggering signal of element 3 begins to form. The output signal duration is equal to tn periods of frequency F. The signal from the output of the element coincidentally 3 is terminated in the same way as in the case with the element of coincidence 2 when a low potential appears on the N-OM output of the register (t ,,, in FIG. 2). Then, after a pause in the n cycles, the signal is formed from the output of the coincidence element 2 (t in Fig. 2g. The duration of the signal from the coincidence element 2 is also equal to mn cycles f. Thus, at the outputs of the coincidence elements 2 and 3, periodic signals are generated the duration of which is equal to mn clock cycles FT and separated from each other by n clock cycles F (fig.2j, 2 | Phase of the trigger signal 1, and hence the output signal of the power amplifier, obtained after summing the signals from the outputs of the elements from dip 2 and 3, differs from phases with drove from flip-flop 8, conventionally taken as zero, for N periods of the commodity frequency F. Processes that cause the formation of signals from the outputs of the elements of coincidence 2 and 3 are periodically repeated, with random failures in shift register 4 and at output trigger 1 no later than after the period of the output signal, they are corrected from the signals to the top 13. The above processes are repeated until the potential change on bus 14 from high to low (tg in FIG. 2c). At the moment of potential change on the bus 14, the propellant shaper 5 is triggered, the output of which is supplied with a low voltage level, which prohibits the passage of signals through the elements 2 and 3. The duration of the inhibit signal is selected so that transients in the load connected to the output , managed to finish, but not less than one period of the output signal. The shift register 4 and the trigger B continue to work as before, but the coincidence element 9 is now locked and the coincidence element 10 is open (moment 2 in Fig. 2d. The output of the coincidence element 10 is connected to the input reset output trigger 1, therefore, after the first change Neither the potential on the bus 14 to the pulse arriving on the bus 13 causes the output trigger to be reset (t in Fig. 2d, e). Thus, the output trigger 1 is set to the opposite state of the trigger 8 at the moment of arrival of the pulse to the bus 13. Start ban signal generator 5 also occurs when the signal on the bus 14 goes from low to high. elements of coincidence 9 and 10, depending on the state of the signal on bus 14, allow phase manipulation, and form the multiplier and in on the output trigger 1. The inclusion of a ban 5 signaling device in the circuit allows, with the phase manipulation method chosen, to avoid voltage spikes in the transistor output stage arising from phase manipulation. In the absence of manipulation signals on the bus 13, this form of the header operates as a periodic signal generator, protected from through-currents through the output transistors. The proposed construction of a driver circuit and pulses is particularly useful when developing multichannel generators with independent adjustment of the phase of the carrier frequency between the individual channels. In addition, for each subsequent channel, you must additionally enter the output trigger 1 and the matching elements 2 and 3. Prohibit signal generator 5 and handler b can be common to all channels. The mutual phase shift of the carrier frequency between the individual channels is determined by connecting the counting inputs of the output triggers and, accordingly, the inputs of the output matching elements to the outputs of the corresponding search bits of the shift register. The device can work without sending a signal to the bus 13. For this, one of the outputs of the register 4 through a shortening chain must be connected to the counting input of the trigger 8 and, respectively, with the inputs of the matching elements 9 and 10. In this case, before starting operation in the ring shift register 4, it is necessary enter an initial state that will be repeated periodically. However, a shaper constructed in a similar way will have a high noise immunity, since in the case of a failure in an annular shift register, its state could not be restored without additional devices specially introduced for this purpose. Claims A pulse shaper comprising an output trigger, the forward and inverse outputs of which are connected to the first inputs of two coincidence elements, the outputs of which are the outputs of a pulse driver, characterized in that, in order to expand the functionality of "simultaneous increase in reliability," an annular shift register, an inhibition signal generator and a manipulator, cocTOja viS from a trigger, two inverters, and two additional matching elements, the first inputs of which are combined n connected to the trigger output, jjTopHe inputs are combined n connected to the first ring-shift input. The gistra, with the input bus and through the first inverter, are connected to the counting trigger input, the third inputs of the additional matching elements, respectively, through the second inverter and directly connected to the bus of the manipulating signal and the prohibitor signal input, the output of which is connected to the second inputs of the matching elements , the third inputs of which are combined and connected to the counting input of the output trigger and with the output of one of the bits of the ring shift register, the second input of which is connected to the periodic bus A sequence of pulses, with the set and reset inputs of the output trigger connected to the outputs of additional matching elements. Sources of information taken into account in the examination 1, USSR Author's Certificate No. 448605, class, H 03 K 21/10, 1972. 2, USSR Author's Certificate f- 563710, class H 03 K 5 / 02.1976 / I 1 1 1 I I but . ti -t Hr-1 fj h GP .Z