SU416843A1 - - Google Patents

Description

one

The invention may be used in communication technology and frequency synthesizers.

There are known pulse sequence converters consisting of an S-flip-flop, the outputs of which are connected to the first inputs of four AND circuits, four logical differential operators.

The purpose of the invention is to improve the speed and reliability of the converter, as well as to obtain the possibility of asynchronous input of the -th formation.

This is achieved by introducing ./ 5-flip-flops with dynamic S-input and register triggers.

The drawing shows a block diagram of the proposed device.

Consider the signals at points 1, 2 in the absence of signals at inputs 3, 4 and the presence of a pulse signal at input 5. If trigger 6 is in the "zero" state, then the same negative differential in input 5 sets trigger 7 at input 8 as well the state is zero, and each successive negative differential confirms this state. If trigger 6 is initially in the state of “unit,” the first negative differential on input 5 rewrites this “unit on trigger 7, the output of which is connected to the input R of trigger 6. In view of this, along with the record“ unit on trigger 7, simultaneously setting to “zero of trigger 6. Another negative differential (dynamic“ zero ”), detected at input 5, sets trigger 7 to“ zero, and subsequent negative differential drops “zero confirm. Thus, in the steady state at the point I there is a zero level.

It also follows from this that setting trigger G to "unit" results in the appearance at point I of a single impulse located between each other by negative drops at input 5. Installation of trigger 6 into "unit is made by a level difference at input 5.

Similarly, a pulse shaper calibrated works, consisting of figger 9, 10, with the top only the difference that writing a format for trigger 10 is dynamically "unit-1, resulting in (as a result of setting trigger 9 in" one) at point 2 the impulse is located between two positive ends that follow each other.

Trigger 11 CLset two controlled counting inputs. Odie: of them. organized with no13,

9

14, 15, in setting the elements

Shems rezhil.o functions in view of the fact that “zero from point 1, doing (with inversion) on

the inputs of the elements 14, 15, opens them, as a result of which the feedbacks from the output of the trigger 11 through the elements 14, 15 to the control inputs of the logical operators are realized. “The zero coming from point 2 keeps the valves 16, 17, and therefore the logical differential operators, closed. If trigger 11 is in the "one" state, then this "unit, entering through the element 14 to the control input of the element 13, allows the formation of a pulse from a positive differential at the dynamic input of the element 13 (input 5). The generated pulse sets the trigger to "zero, whereby element 14, and therefore element 13, are blocked, and elements 15 and 12 open, with the result that the next positive differential arrives at input 5 of trigger 11, setting the latter to" one state.

Thus, in the steady state, the trigger 11 performs a division of the frequency of the pulses fed to the input 5, triggered by a positive differential. When a signal arrives at input 3 (in this case, in the form of a negative differential), a pulse is formed at point 1, covering elements 14 and 15 (therefore, prohibiting triggering of the I trigger) for the time between two adjacent negative differential signals at input 5. Since during this time only one positive differential is necessary and possible, it follows that with a signal (differential) at input 3, trigger 11 is prevented from triggered by one positive differential at input 5, which is equivalent to knocking out and an impulse from the sequence arriving at input 5.

Thus, when the number of pulses at input 5 is equal to “i (for an arbitrarily taken length of time) and the number of pulses at input 3 equal to HZ, the number of pulses will occur at the output of the converter (in the absence of a signal at input 4)

(fii - nz) 2

When a signal arrives at input 4, a positive pulse is generated at point 2, which allows one-time triggering of trigger 11 from a negative differential at input 5 by opening valves 16, 17 for the time between two positive differences. The flip-flop of trigger 11 is carried out by a "single pulse generated at the output of an open logical operator (18 or 19 depending on the state of flip-flop 11) when applying and its dynamic input of a negative differential. This operation is equivalent to the appearance of an additional pulse in the HI sequence; thus, when the number of pulses at the input 5 is equal to "i (for an arbitrarily taken time interval), the number of pulses per

the input 3, equal to "2, and the number of pulses at the input 4, equal to pz, the output of the converter 20 will be the number of pulses

(d, -Pa + h) 2

Logic elements with dynamic (and thermal) inputs that react to signals of a different sign can be used in the device. In this case, autonomous inverters can be used to implement the circuit (“NOT” circuits).

Subject invention

A pulse train consisting of ./ 5-flip-flop, the outputs of which are connected to the first inputs of four AND circuits, four logical differential operators, characterized in that in order to increase speed and reliability, as well as to enable asynchronous information input , introduced 5-triggers with dynamic 5-input and

register triggers, the output of the first / 5-trigger with dynamic 5-input is connected to the input of the first register trigger, the synchronization input of which is connected to the dynamic inputs of logical differential operators and the synchronization input of the second register trigger, the output of which is connected to the ./-input of the second RS trigger with dynamic 5 input, the output of the latter is connected to the input of the second

register trigger, and the output of the first register trigger is connected to the ./-input of the first ./ 5-flip-flop with a dynamic 5-input, and also connected to the second inputs of the first and second circuits "And, the output of the second register trigger is connected to the second inputs of the third and fourth “And, and the synchronization inputs of the first and second register triggers and dynamic inputs of logical differential operators are connected to the input of the pulse train.