CS217921B1 - Connection for generation of synchronnous impulses - Google Patents

Abstract

The invention relates to computer technology. The problem is generating synchronization pulses for digital computers. The essence of the invention is that to the output of the primary synchronizer generator pulses is connected at least one branch of the double primary line resistive synchronization wiring and the turns to which they are secondary synchronization generators are connected pulses. The invention can be utilized in the art computing and measuring techniques.

Description

The invention relates to a circuit for generating synchronization pulses which is used in a computer base unit.

The synchronization pulses ensure synchronous operation of the logic circuits in the modules and the entire modules of the computer base unit and divide the time into equal intervals. The beginnings of the time intervals indicated by the rising edge of the pulses are the same throughout the base computer unit. These are therefore isochronous impulses.

The known circuitry for generating synchronization pulses uses, for example, an idle oscillator which, with the combination and sequential logic network connected, generates a series of synchronization pulses that are distributed, typically in a radial fashion, to different parts of the logic of the computer base unit. Thus, the wiring for generating is dispersed in the logical structure of the base unit and does not form separate functional or structural units. Therefore, for each configuration of the base unit it is necessary to deal with the generation wiring separately.

The above-mentioned disadvantages are eliminated by the synchronization pulse generating circuit according to the invention, characterized in that at least one branch of the resistive-terminated primary synchronization circuit and the taps to which the secondary synchronization pulse generators are connected are connected to the output of the primary synchronization pulse generator. The pulse interval monitoring circuit, the pulse interval monitoring circuit, and the synchronizer for starting and stopping the synchronization pulse generating circuit are connected in the primary sync pulse generator circuit, and also the monitoring circuit is connected in the secondary sync pulse generator circuitry. pulse alternating circuits.

The accuracy of the repetition rate, ie the cycle length, the position of the generated pulses, ie the incrementality of the leading edges of the pulses and their width must be maintained with an accuracy of + 1 ns. The leading edges of the pulses generated by the individual secondary synchronization pulse generators at different distances from the primary generator must be identical in time.

The logical structure of the computer base module modules requires that an additional delayed synchronization pulse be generated in the middle of a basic time interval of, for example, 125 ns. The primary synchronization pulse generator must start and stop in a defined interval between pulses. The accuracy of the pulse generated times depends on both the primary and secondary sync pulse generator. The primary generator accurately determines the sync pulse length and the second sync pulse delay, while the secondary generator accurately determines the width of the output sync pulses.

An example of a circuit for generating synchronization pulses according to the invention is shown in the attached drawing, wherein Fig. 1 shows a block diagram of a synchronization pulse generator. Fig. 2 shows a block diagram of a primary synchronization pulse generator.

The main outputs 11 and 12 of the primary generator £ synchronizing pulses which is' designed as separate subassembly electrostatic shields are connected two cable branches 2 _T T primary synchronization timing. Two secondary synchronization pulse generators 6 are connected to each cable branch 2, 4 '

Each cable branch 2, 2 'is terminated by a resistive terminating member 6, 6. Secondary generators 6 (not shown) are connected to the outputs 8, 6 of the secondary wiring (not shown) which radiate to individual loads in the module logic. are the control inputs of the entire circuit for generating synchronization pulses.

The primary synchronization pulse generator (6) controls the operation of the secondary generators (6) by means of a pair of pulses which are transmitted by cable line (2, 2). The secondary generators 6 generate out of these pulses the output synchronization pulses for the module logic. The cable conduit 2, 2, is formed by a coaxial cable and is a separate conduit in a computer base unit that is structurally different from other conduits.

The primary synchronization pulse generator (FIG. 2) comprises an idle repeater frequency generator 21 connected to the first input of the synchronizer 22, to the second input of which the delay circuit 23 is connected with the US input. The first output of the hand-held control circuit 24 is connected to the third input of the synchronizer 22, the second output of which is connected to the first input of the monostable circuit 25. The fourth input of the synchronizer 22 is connected to the input terminal 17 of the primary generator circuit. The output of the monostable circuit 25 is coupled to the input of the delay circuit 26 whose output is connected to an output circuit 27 having an output terminal 11. The output of the monostable circuit 25 is also coupled to an output circuit 28 having an output terminal 12. K the first input of the watch circuit 30, the second input of which is connected to the terminal 12 of the output circuit 28, is connected to the output terminal 18, the input of the second watch circuit 29, the output of which is connected to the output terminal 15. while the output of the watch circuit 30 is coupled with output terminal 16.

From the idle generator 21, which starts immediately after the supply voltage has been switched on, pulses arrive at the synchronizer 22. The synchronizer 22 is controlled by a signal from the delay circuit 20 delaying the start of the primary synchronization pulse generator circuit upon the external control signal. control 24 allows the primary generator to be operated (start, stop, single start) using the buttons located on its panel. The start and stop of the primary generator can be controlled by a signal supplied from the computer service module to the terminal 17 of the synchronizer 22.

The manual control circuit 24 controls, on a single start, a monostable circuit 25 which generates the width of the output synchronization pulses of the primary generator. The pulses from the monostable circuit 25 are fed to the first output circuit 28, which generates the first output sync pulses at its output terminal 12. From the circuit 25, the pulses are also routed to the delay circuit 26, which creates the delay necessary for correct timing of the second sync pulse generated. A second output circuit 27 on output terminal 11. The signal of correct operation of the primary synchronization pulse generator is taken from the output terminal 15 of the pulse interval monitor 29 and from the output terminal 16 of the pulse rotation monitor 30.

In the secondary synchronization pulse generator (FIG. 3), the input terminal g is coupled to an isolation and equalization circuit 31, the output of which is coupled to an edge-derived circuit 32. The output of this circuit 32 is connected to a monostable circuit 33, the output of which is connected to a power circuit 34 having an output terminal 8. Likewise, a second part of the secondary generator is connected where the input terminal J is connected to a separation and equalization circuit 31. is coupled to an edge-derived circuit 32 ', the output of circuit 32' being coupled to a monostable circuit 33 ', the output of which is coupled by 8 power circuit 34'. The second inputs of the monostable circuits 22 and 11 'are connected to the terminal 10 for setting the initial state of the secondary generator.

The setting input of the pulse-to-pulse monitoring circuit 35 is also connected to terminal 10. The other two inputs of the circuit Jg, which serve for the supply of alternating pulses, are each connected to their input terminal 13 resp. The monitoring circuit 35 has an output terminal 19.

The input terminals 6 and 7 are supplied with pulses from the branch of the cable branch 2. 2 .. '

Separation and equalization circuit 31 resp. 31 'separates the secondary synchronization pulse generator from the cable line and compensates for the delay in the line so that the leading edges of the output pulses of all the secondary generators g connected to the cable branches 2 and 2 ' Pulses from circuit 31 resp. 31 ' 32. * in which a narrow pulse is derived from the edge of the incoming pulse, which triggers the following monostable circuit 11, respectively. That affects the width of the output pulse. From circuit 33 resp. 33 ' 34. ' which supplies the output pulses taken from terminal 8 and 8 respectively. fi logical gain. The initial state of the circuits 33, 33 'and 35 upon power-up is set by the signal applied to terminal 60. The output sync pulses of the secondary generator are supplied to terminals 13 and 14 from terminals fi and fi. The circuit 35 monitors the alternation of the applied pulses. A signal from the fifi output terminal indicates that the secondary generator is running correctly.

The circuit for generating the synchronization pulses according to the invention is suitable for use in digital technology, in particular in modular structure computers or in measuring technology.

Claims (3)

Synchronous pulse generating circuit, characterized in that at least one branch (2,2 ') of a double synchronous primary wiring with a resistive termination (5.5 *) and taps is connected to the output of the primary synchronization pulse generator (1). to which the secondary synchronization pulse generators (4) are connected. 2. The synchronization pulse generating circuit as set forth in claim 1, wherein a circuit of the pulse rotation alternating circuit (30), a pulse interval monitoring circuit (29) and a starter synchronizer (22) are connected in the circuit of the primary synchronization pulse generator (1). stopping the wiring to generate synchronization pulses. 3. The circuit for generating the synchronization pulses according to claim 1, characterized in that pulse alternating monitoring circuits (35) are connected in the circuits of the secondary synchronization pulse generators (4).