CS213448B1 - Wiring to release passage and feed signals - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to a method for releasing signal passages, particularly in the field of dedicated discrete automata. The present invention solves the release of the passages of the individual inputs not associated outputs associated with arbitrarily extending their duration, combined with the possibility of moving in both directions, achieved by bringing down signals to one feed line and ns a second feed line. The essence of the invention lies in the individual signal lines comprising signal elements, for example thyristors through gates formed by transistors. The details of this interconnection are included in the definition and shown in the drawing. The invention is applicable to discrete automata solutions that address the release of signal passages with the possibility of bidirectional displacement of these signals.

Description

The invention relates to a circuit for releasing a signal shift passage 8, in particular in the field of dedicated discrete automata.

Known connections release signals from individual inputs to assigned outputs individually, for example, in order of time, in sequential order, in combined order, and the like

A disadvantage of the known wiring is the release of the passage of the next input signal only after the previously released signal has disappeared.

These drawbacks are eliminated by the wiring for releasing the passage and shifting of the signals composed of N inputs and N outputs assigned to each of these inputs so that each individual input is connected to the associated output via one signal line of the lowered 2 of a single thyristor switching element. the switching element control electrode via one resistor and the switching element anode is connected via a capacitor to the switching element anode in the order of the next signal line, and through a second resistor to one supply line, while the switching element cathode is connected to the second supply line through a parallel combination of the third resistance; a second capacitor, characterized in that the switching element cathode _u e is connected to the control electrode of the signal line switching element via a sixth base resistance of a second transistor whose emitter is connected to the switching element electrode and the collector p the seventh resistance with the second shifting guide.

The advantage of the signal release and shifting circuit according to the invention is the release of the signal from the individual inputs to the associated outputs associated with any extension of its duration, combined with the possibility of shifting in both directions achieved by applying shifting signals to one shifting line and shifting line.

The wiring for releasing the signal passage and shifting according to the invention is shown in the drawing in an exemplary embodiment.

; In the drawing, a first input connected through a first resistor ^ R ^ of the first signal line to the control electrode of the switching element of the first signal line is shown. The anode of this switching element + is connected via a second resistor R1 of the first signal line to one supply line U. The cathode of this switching element is connected via a third resistor ^ R ^ connected in parallel with the second capacitor of the first signal line to the second supply line Oas with the first output X. ^, assigned to the first input Sy.

Shown is the second input S ₂ is connected via a first resistor Rg ^ second signal lines with řífclicí electrode of the switching element T ₂ of the second signal line. The anode of this switching element T ₂ (is connected via a second resistor of the second signal line to one supply line U. The cathode of this switching element T ₂ is connected via a third resistor ^ R ₂ connected in parallel with the second condenser Cg of the second signal line with the second the supply line Oas through the second output X ^ assigned to the second input S ₂ .

The women of the third entry S- ,.

The longer input S _N connected through the first resistor R R delší of the longer signal line e is shown by the control electrode of the long signal line switching element T řídicí. Aneda of this switching element 2

That is, it is connected via a second resistor R ^ of the longer signal line to one supply line U.

The cathode of this switching element T _N is connected via a third resistor ^R ^ connected in parallel by a second capacitor C Cj of the next signal line to the second supply line Ose through a longer output X _K , assigned to the other input S ^. . .

The signal lines are interconnected tsk, that the anode of the switching element T ^ of the signaling line is connected to the anode of the switching element Tg of the second signaling line through the first capacitor of the first signaling line. through the first capacitor of the second signal line, the anode of the switching element T ^ of the third signaling line is connected to the anode of the switch element T dalšího of the next signaling line through the first capacitor Ji of the third signaling line.

The switching element cathode Ty of the first signal line is connected to the control electrode of the switching element Tg of the second signal line through the first transistor Ag of the second signal line so that the base is connected to the cathode via the fourth resistor R Rg of the second signal line. , and the collector is coupled via a fifth resistor R Rg of the second signal line to one shift line P.

The cathode of the switching element Tg of the second signal line by the control electrode of the switching element T1 of the third signal line through the first transistor A1 of the third signal line so that the base is connected via the fourth resistor ^ R třetí of the third signal line to this cathode, the emitter is connected to this control electrode, and the collector is connected via the fifth resistor R R třetí of the third signal line to one shifting line P.

The cathode element spínecího T ^ a-regional third conduit is connected to the control electrode ⁵ Whose switch an element T ^ next signal line via the first transistor and the signal lines extended-TEK, the base is connected via a fourth resistor _Λί Ν longer signal lines with the cathode, the emitter is coupled to this control electrode, and the collector is coupled via a fifth resistor r to the next signal line to a single shift line P.

The outputs X _N are connected to the cathode of the switching elements _Τ χ Tg, T ,, .. T ^ _N such that the cathode of the first switching element Ty signal lines is connected to the first output XY switching element cathode Tg of the second signal lines is connected the second output Xg, the cathode of the switching element of the third signal line is connected to the third output X ^, std., the ketode of the switching element T _{N of the} other signal line is connected to the longer output X _N ·

Signal lines are also connected so that the cathode of the switching element of the Tg of the second signal lines is connected to the control electrode of switching element Ty first signal line via the second transistor should first signal line so that the base is connected through a sixth resistor ⁶ y first signal lines to the cathode , the emitter is connected to this control electrode, and the collector 7 is connected via the seventh resistor Ry of the first signal line to the second shift line Z.

The cathode of the third signal line switching element T2 is connected to the second signal line switching element Tg via the second signal line trenzister Bg so that the base is connected to the cathode via the sixth second signal line resistor ^ Rg, the emitter is connected to the control electrode , and the collector is connected via a seventh resistor? Rg of the second signal running on the line with the second shifting line Z.

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The cathode of the switching element Tj third signal line is connected to a gate electrode of the switching element T ₂ of the second signal line via the second transistor B ₂ of the second signal line Jtek the base is connected via a sixth resistor R iv ₂ the second signal lines with the cathode emitter is connected by this control electrode, and the collector is connected via the seventh resistor R _{2 of the} second signal line to the second shift line Z.

The cathode of the switching element T _{N of the} longer signal line is connected to the control electrode of the switching element T of the third signal line through the second transistor Bj of the third signal line so that the base is connected via the sixth resistor R · of the third signal line to this cathode. , the emitter is connected to this control electrode, and the collector is connected via the seventh resistor R 3 of the third signal line e to the second shift line Z.

For example, a thyristor is provided as the switching element. One supply line U represents a positive supply line, the other supply line represents a zero supply line of the DC-supply network.

The wiring function for releasing the passage and shifting of the signals according to the figure is flowing, that by default all signals S ^, S ₂ , Sj, ..., the signal and the zero logic level are lower than the switching threshold voltage of the switching elements prvků · ρ T _g , T ₃ , ..., T _N , which are open. On the anodes of these switching elements, and therefore on the output X ^, _X2, Xj, ..., X _N is a signal of logic level zero. By applying a one-level logic signal to, for example, the second input S ₂ , this signal passes to the control electrode of the switching element T _{2 of the} second signal line and causes the element to switch on. The result is a one-level logic signal at the second output X ₂ , and its duration is independent of the duration or extinction of the signal n with the second input Sg upon completion of the transient event. It is sufficient to apply a short signal to the respective input to bring the switching element of the individual signal line to the closed state.

In the following, it is assumed that the inputs are excited by signals without timing overlap.

Subsequent to the application of a signal, for example to a third input, the signal passes to the control electrode of the switching element T1 of the third signal line and causes the element to be switched on. The result is a one-level logic signal at the third output X1.

Following the previous closed stev second signal lines acting transient process bringing into the closed state the third signal line to said second signal line so that the voltage drop to a tan switching element T ^ is transmitted through the first condenser-C ₂ of the second signal line no anode switching element T ₂ and causes it to open, which results in a change in the logical value of the signal at the second output X _g .

In general, the signal applied to the individual input immediately transitions to the assigned output and causes the signal to be erased at the previously energized output. In this case, the function of one shifting line P is such that the signal applied to these shifting lines causes the signal to be shifted from the previously energized output to the output in the order of output.

Tek does not attach when in the initial state signal is not energized second output X ₂ represents the shift excitation signal ns, the third output X ^ the current extinction signal at the second output x _g. In this displacement, the connection of the signal lines is effected by transistors A ₂ , A 1, ..., A _N operating as the center with the direction of passage always from the cathode of the switching element of the single signal line to the control electrode of the switching element in the order of the longer signal line.

It is obvious that the signal applied ns jedns shift line P passes through the fifth resistor ² '= ^H 3 ***** \ J ^{e <3netl 4-ch} signal lines not collector of the first transistor Ag, N, .., AN these signal lines. Because of the relatively high voltage level at the cathode of the second signal line switching element Tg, the first signal line transistor opens, releasing the signal transition to the third signal line switching element control electrode T1. Eventual transmission to the next signal line is prevented by the time constant of the RC member, i.e., the time constant of the third resistor ^ R ^ and the second capacitor ^{20 of the} third signal line, which temporarily maintains the cathode voltage T3 of the third signal line. The de-open state of the second signal line switching element Tg is effected by transferring a voltage drop from the third signal line circuit element Tg through the second signal line capacitor Cg to the anode of the second signal line switching element T2, as previously described.

Due to the connection of the cathodes of the switching elements of the individual signal lines with the outputs, the logic zero or logic 1 levels of the inputs and outputs are identical. Due to the bi-directional interconnection of the signal lines by the transistors and their connection to one shifting line and the other shifting line, a forward shift is possible in the direction of increasing indices, which is effected by feeding the previously defined signal to one shifting line P indicating the serial number of the input and the associated output.

Pseuv vzsd proceeds Tek, for example, the default closed STSV switching element T ₂ of the second signal line is the second output signal Xg logic one. By applying the signal n to the second feed line Z, this signal passes through the seventh sdpsr 7 _{R 1} , R 8, ... unity i

vidual signal lines to the collector of the second transistor B ^, B _2, B ^, ... těchťóWignálních line. Due to the relatively high level of stresses at the cathode of the switching signal Tg of the second signal line, the second transistor B ^ of the first signal line opens and releases the transition of the beta to the control electrode of the switching element T ^ of the first signal line. The disconnection of the second signal line switching element Tg is effected by transferring a voltage drop from the first signal line switching element T2 through the first capacitor of the first signal line ns of the second signal line switching element Tg.

The signal release and shifting circuit according to the present invention is used in the solution of single-purpose discrete automata that solve the release of the signal β through the possibility of bidirectional shifting of these signals.

Claims (1)

SUBJECT OF THE INVENTION Wiring for releasing the passage and displacement of signals composed of N inputs and N outputs assigned individually to these inputs, so that each individual input is connected to the associated individual output via one signal line consisting of one switching element, eg a thyristor, where the input is connected to the switching control electrode the element via one resistor and the anode of the switching element is connected via a condensate to the anode of the switching element in the order of a longer signal line, and through a second resistor to one power line, while the cathode of the switching elements is connected to the second power line via a parallel combination of characterized in that the cathode of the switching element (Tg) is connected to the control electrode of the switching element (τρsignal via a sixth resistor) at the base of the second transistor (Bp) whose ernitor is connected to the control electrode of the switching element (T ^) or (fye by second shift guide (Z)).