DE1044165B - Photoelectric bistable multivibrator - Google Patents

Description

GERMAN

Under a bistable trigger circuit or flip-flop circuit is a trigger circuit with two stable operating states, which can be switched over by an externally initiated control process can be understood. Any overturning from one stable state to the other can be avoided triggered by an impulse. Electron tubes are used as components in the known bistable multivibrator circuits or gas-filled discharge tubes or transistors or ferrite cores are used. The basic principle this bistable multivibrator goes to the two-tube circuit specified by E c el es and Jordan back, which, with suitable dimensioning, also has two stable operating states, such as that ζ. B. in the first operating state, "one" half of the two-pipe system of electricity, leads and thereby at the same time causes the "other" half of the two-pipe system to be blocked. In the second operating state if the situation is exactly the opposite, in that the "other" half conducts electricity and thus one Blocking of "one" half of the two-pipe system brings about. The tilting process, d. H. the overturning between the two operating states is carried out in the known bistable tube flip-flop circuits initiated appropriate, the anodes or the grids or the cathode impressed pulses. The bistable Toggle switching is versatile in electronics, especially in electronic circuit technology Use, e.g. B. for generating square wave voltages or as a storage element or as a counting circuit or as a pulse reducer. The bistable flip-flop is particularly popular for electronic Calculating machines used.

The well-known bistable two-tube flip-flop circuit usually consists of two identical and through Voltage divider and coupling capacitors coupled tubes (FKp flop halves). the The anode of the first tube is connected to the grid of the second tube and the anode of the second tube coupled to the grid of the first tube.

It is also already known in a bistable two-tube flip-flop circuit instead of the Coupling resistor or in series with the coupling resistor or instead of the grid discharge resistor or to switch a photocell in parallel to this. This means that the tilting circle can be caused by lighting fluctuations be made to tip over. The photocell acts as a resistor, its own The value changes with the incident illuminance. With the development of the photoelectric bistable The object underlying the invention is concerned with flip-flop.

For a photoelectric bistable multivibrator, the invention consists in that in both Photoelectric bistable trigger circuit

Applicant:

IBM Germany

International office machines

Gesellschaft mbH,
Sindelfingen (Württ), Tübinger Allee 49

Dr.-Ing. Arno Schulz, Sindelfingen (Württ.),
has been named as the inventor

Flip-flop halves each one gas-filled, one on its own Working area effective photocell is arranged, the electrode of which has a variable potential with the respective is coupled to others and which is controllable in this work area by the radiation, so that at Removal of the radiation has the effect of a memory that occurs when switching over to the other Operating state of the bistable multivibrator is deleted.

The well-known bistable two-tube circuit takes the place of one or both electron tubes According to the invention, a gas-filled photocell, which is not, as was previously the case with the conventional gas-filled Cesium oxide and cesium antimonide photocells common in the dependent discharge area, but in the independent discharge area is operated, and that fatigue-free, d. H. stable without the photocurrent decreases continuously with the duration of the irradiation or the independent discharge. the Storage effect of the photocell used in the invention can be advantageous by relocating the Working point set up can be canceled from the independent in the dependent discharge area be. In addition, there is an optional signal storage by varying the stabilization impedance possible.

The advantage of the bistable multivibrator is over the known photoelectric bistable Flip-flops in a significant simplification of the circuit and a considerable saving Circuit elements.

In the independent discharge area, such gas-filled photocells can preferably be operated, which have a thin-film photocathode. With

"09 67971"

thin-film cathodes give you high field strengths in the photocathode, which in turn has the consequence that one is bound in the traps Charge carrier gets into the conductivity band. Under thin layer is understood here that the Cathode layer should be at least a factor of 10 to 100 thinner than the known commercially available gas-filled casium oxide photo cells.

Gas-filled photocells with potassium hydride cathodes prove to be particularly advantageous for the invention. These can easily be operated in the independent discharge area if their cathode is sufficiently thin. Potassium hydride can be produced very easily in thin layers.

In order to be able to operate a gas-filled photocell in the independent discharge area, one can according to the invention also use photocells in which between the photocathode and a special A pre-discharge is burning. The one burning between the auxiliary electrode and the cathode Discharge is then in use on the discharge space between the main anode and the photocathode reversed.

It is also useful if the used in the bistable trigger circuit according to the invention Photo cell has a particularly high filling gas pressure and if the filling gas of the photo cell is polyatomic Vapors are added. It is also advantageous if the filling gas of the photocell is admixed with gas contains, such that the excitation voltage of the main gas is greater than the ionization voltages of admixtures. It is also advantageous for the purposes of the invention if the gas-filled Photo cell has particularly large internal electrode gaps.

The invention is described below with reference to the drawings for some exemplary embodiments explained in more detail.

Fig. 1 shows some characteristics of the gas-filled photocell, as they are in the arrangement according to the invention to be used;

Fig. 2 shows the circuit of an embodiment of the invention;

Fig. 3 shows a further embodiment of the invention.

In Fig. 1, current-voltage characteristics are shown as they can be measured on the gas-filled photocells used in the invention. The upper curve in FIG. 1 applies to the case in which the photocathode of the gas-filled photocell is not irradiated or exposed, ie when Φ = 0. It practically corresponds to the current-voltage characteristic of a glow discharge. The ignition point is designated by Z for this upper characteristic curve. It lies on the ordinate axis, because the pre-currents in a gas-filled photocell are so small without cathode irradiation that they cannot be represented on a linear scale.

If, on the other hand, the photocathode is irradiated with a luminous flux Φ , the lower characteristic curve (Φ > 0) occurs. For the lower curve , Z 'is the ignition point. The ignition voltage has therefore been reduced and the ignition currents shifted towards higher values.

If you now connect the gas-filled photocell, the characteristics of which are shown in Fig. 1, in series with a stabilizing resistance R _s to a driving voltage U ₀ , the following results: The resistance line of this resistance R _s drawn in in Fig. 1 cuts the current -Voltage characteristics for the case of irradiation of the photocathode in point A and for the case of darkness in point B. The following functional sequence results when using the circuit: First, the gas-filled photocell is connected to the driving voltage U ₀ without cathode exposure. The resulting working point is U ₀ on the ordinate axis. The photocathode is now irradiated. The new operating point is now A on the current-voltage characteristic for Φ > 0. A current I ₁ flows through the gas-filled photocell . After removing the photocathode exposure, an independent discharge with operating point B remains. The current i " now flows through the gas-filled photocell.

The photoelectric flip-flop circuit according to the invention shown in FIG. 2 consists of the two gas-filled photocells F ₁ and F ₂ , which can be operated in the independent discharge area, with the associated stabilization resistors Ji ₁ and i? ₂ and the capacitor C.

In the arrangement according to FIG. 2, the two gas-filled photocells F ₁ and F ₂ are connected to the common DC voltage source U ₀ . The resistors R ₁ and R ₉ serve to stabilize the glow discharge . The light transmitter L scans z. B. a passing punch card LK , in such a way that with each perforation of this card LK a light pulse hits the photocathodes of both gas-filled photocells F ₁ and F ₂ . Then, as a result of slight deviations in the level of the ignition voltage, a glow discharge will ignite in one of the two photocells. We assume that this is the photocell F ₁ . The anode voltage of this cell F ₁ then breaks down to the burning voltage of the glow discharge. This has the consequence that the anode of the cell F _2, as a result of the capacitance C, briefly assumes the same voltage, so that the photocell F ₂ cannot ignite. If the next light pulse (e.g. from another hole in the punched card LK) hits the two gas-filled photocells F ₁ and F ₂ , the photocell F _{2 will} now ignite, because the capacitor C is now charged, and at the anode the photocell F ₂ is now at full voltage U ₀ . At the moment F _{2 is} ignited, an equalizing current flows from the capacitor C via R ₂ and R ₁ , which suppresses the operating voltage of the cell F ₁ and leads to the extinction of the independent discharge in this photocell. The next light pulse then causes a glow discharge to ignite _{again in F 1.} If one were to switch on a relay M in the right flip-flop half fainter R ₂ and in series with R ₂ , then, as can be seen from the above, only every second light pulse of this relay M would respond. B. represent a pulse translator and cause a count of the reduced pulses. In place of this relay M , if necessary, a glow lamp can also be used, which is parallel to the photocell F ₂ and indicates its operating status. Depending on the use and application of the circuit according to FIG. 2, an output pulse I _a can be taken either at point α or an output pulse I _b at point b .

In the arrangement according to FIG. 3, the two photocathodes sit with their anodes of the two flip-flop halves in a common vessel or tube bulb. An ionic shield N , which is connected to earth, is provided between the two tube systems F ₁ , F _2. If necessary, a common anode can be assigned to the two photocathodes F ₁ , F _2.

When used in electronic computing devices, the circuit of Fig. 1 or 3 would be a single one

Represent stage of the counting chain. You can then this counting level z. B. expand to a decade counting chain. It would be possible to expand the circuit according to FIG. 2 or 3 to, for example, ten gas-filled photocells, all of which are operational in the independent discharge area. These ten photocells are then to be arranged side by side in such a way that their cathodes are jointly hit by the same light pulses. In this case, it is expedient to use optical conductors (light guides) emanating from the light source L , one of which each leads to a photocell or a photocell stage.

One can also restrict oneself to setting up only the first flip-flop stage with gas-filled photocells which are operational in the independent discharge area and to use known tube circuits or transistor circuits or magnetic core circuits for the remaining flip-flop circuits. This case is dealt with in FIG. 3, where at point b the circuit D made up of the further flip-flop circuits is connected. The functional sequence is the same as that of a counting chain that alone z. B. is composed only of Eccles-Jordan circuits. The circuit according to FIG. 3 can easily be extended to several decades.

Claims (16)

Patent claims: 1. Photoelectric bistable flip-flop circuit, characterized in that a gas-filled photocell (F ₁ , F ₂ ) is arranged in each of the two flip-flop halves, the variable potential of which electrode is coupled to the other and which is in this Working area can be controlled by the radiation, so that when the radiation is removed, the effect of a memory occurs, which is deleted when the switch to the other operating state of the bistable multivibrator. 2. Arrangement according to claim 1, characterized in that to switch from one to the other stable operating state, two gas-filled photocells (F ₁ , F ₂ ) are simultaneously impressed light pulses. 3. Arrangement according to claims 1 and 2, characterized in that the anodes of the two gas-filled photocells (F ₁ , F ₀ ) are connected to one another by a charging capacitor (C). 4. Arrangement according to claims 1 to 3, characterized in that the storage effect of the gas-filled photocell (F ₁ , F ₂ ) in the live state can be canceled by shifting its operating point from the independent discharge area to the dependent discharge area. 5. Arrangement according to claims 1 to 4, characterized in that the signal storage of the gas-filled photocell (F ₁ , F ₂ ) can be controlled by changing the stabilization resistor (R ₁ , R ") of this photocell (F ₁ , F ₂ ). 6. Arrangement according to claims 1 to 5, characterized in that the operating voltage (U ₀ ) of the gas-filled photocell (F ₁ , F ₂ ) is only slightly smaller than the ignition voltage (U ₂ ) of this tube in the case of non-irradiated photocathode. 7. Arrangement according to claims 1 to 6, characterized in that _{a pre-discharge burns in the gas-filled photocell (F 1} , F ₂ ) between the photocathode and an auxiliary electrode. 8. Arrangement according to claims 1 to 7, characterized in that the gas-filled photocell (F ₁ , F ₂ ) contains a thin-layer photocathode. 9. Arrangement according to claims 1 to 8, characterized in that the gas-filled photocell (F ₁ , F ₂ ) contains a thin-layer potassium hydride photocathode. 10. Arrangement according to claims 1 to 9, characterized by a gas-filled photocell (F ₁ , F ₂ ) with particularly large internal resistances. 11. Arrangement according to claims 1 to 10, characterized by a photocell (F ₁ , F ₂ ) with a particularly high filling gas pressure. 12. Arrangement according to claims 1 to 11, characterized by a photocell, the filling gas polyatomic vapors are added. 13. Arrangement according to claims 1 to 12, characterized by a gas-filled photocell (F ₁ , F ₂ ), the filling gas contains an admixture, such that the excitation voltage of the main gas is greater than the ionization voltages of the admixtures. 14. Arrangement according to claims 1 to 13, characterized in that the photocathodes of the two flip-flop halves are arranged in a common tube piston. 15. Arrangement according to claim 14, characterized in that between the two photocathodes an ionic shield is provided. 16. Arrangement according to claims 14 and 15, characterized in that the two photocathodes a common anode is assigned. 1 sheet of drawings © SOS 679/147 11.58