DE1172452B - Sequential circuit - Google Patents

Description

Sequential circuit Sequential circuits as they are, for. B. in computing systems and other logic devices were first developed empirically; now their development is gradually becoming a science. The circuit algebra was in detail, z. B. at Richards, Arithmetic Operations in Digital Computers, Van Nostrand, 1955; P h i s t e r, Logical Design of Digital Computers, Wiley & Sons, 1958; and C a 1 d w e 11, Switching Circuits and Logical Design, Wiley & Sons, 1958. There are various analytical methods for simplification of circuits have been proposed that help address the shortcomings of existing circuits can be determined and in some cases an optimal circuit is realized can be.

C a 1 d w e 11 outlines a system for building electronic circuits according to a "river table". The "flow" (or the switching sequence) runs on this Diagram showing a series of horizontal rows of boxes which are separated by intersecting horizontal and vertical lines are formed downwards. The boxes are marked according to the function determined by the column position. The ordinary sequential circuit conducts at any point in its operation a history, indicates a current state (by the position in marked on the flow chart) and can assume several future states. The choice of the future state depends on the current state and the input signals away. The river table shows the prehistory by numbering; she usually has one steady state for each row or history period and one unstable Switching state between two stable states.

All sequential circuit problems can be represented by flow charts. For example, a bistable multivibrator or a two-part counter is a device that can be described in a four-row table with eight boxes as follows: Input signal I + I. Step a. . . . . . . . . . . . . . . . (1) 2 Step b. . . . . . . . . . . . . . . . 3 (2) Step c. . . . . . . . . . . . . . . . (3) 4 Step d. . . . . . . . . . . . . . . . 1 (4) Unstable state: 1 2 3 4; Input signal: Stable state: (1) (2) (3) (4); Output signal: In the simplest form of a two-part multivibrator counter, the alternating input signals have a fixed frequency. The output signal appears alternating with half the input frequency. There is a steady state in which both the input and the output are turned off and other stable states in which either the input or the output or both are energized. A switching function occurs for every change of state as follows: (1) The output remains switched off.

2 Input energized to energize output. (2) Output remains energized.

3 input switched off. (3) Output remains energized.

4 Input energized to turn off output. (4) The output remains switched off.

1 input switched off.

The resulting flow chart describes the sequential circuit exactly and without ambiguity, repetition or gaps. Known follow-up circuits were partly by interpreting the flow chart from electrical logic circuits, such as B. AND, OR, inverter or the like circuits developed.

The invention is concerned with creating sequential circuits directly from the river table. In a Embodiment of an inventive Sequential circuits should exclusively use neon photoconductor elements as switching elements be used.

The sequential circuit according to the invention is implemented with the aid the known flow chart describing the successive switching states and is characterized in that each column of the flow table has a column and each row of the flow table corresponds to a row conductor that the input signals the Column conductors are fed that the output signals from the switching states the row ladder can be modified that at the steady states of the flux table corresponding crossing points of column and row conductors interlocking circuits are provided that keep the connected row conductor prepared, as long as the connected column conductor is excited, and that to the unstable States of the flow table corresponding crossing points of the column and row conductors transmission circuits are provided, which the preparatory state of each transferred to them connected row conductors to one or more row conductors, when the column conductor connected to the transmission circuit is energized.

The finished sequential circuit, which can be accommodated in the smallest of spaces, is recognizable as a river table in practical execution. There will be two types of logical Switching elements used: the logical locking element and the logical transmission element. Each locking element creates a stable state; through each transmission element a stable state is transmitted from one locking element to another. A transmission element can have two locking elements that go through many steps of history are separated from each other, connect, thus skipping steps, it can also reverse the history and go back several steps, after which the steps can be repeated.

In practice, the flow table logic consists of several vertical and several horizontal ladders arranged in a grid. the vertical conductors are insulated from the horizontal conductors. The vertical ladder correspond to the left line of the corresponding columns in the flow chart, and the horizontal ones Ladders correspond to the baseline of the corresponding rows of river tables. The logical one Latch circuitry is connected to the column and row conductors, whose Intersection corresponds to the stable state block in the flow table.

The interlock circuit is used depending on the component used self-locking or regenerative feedback to be one of two stable ones To accept and maintain conditions that are “prepared” and “not” below prepared «, and also the associated row leader in the prepared or not to keep the prepared state.

The logical transmission element that corresponds to the unstable state in the Flux table is a circuit that corresponds to the preparation of your own Row ladder prepared a locking element in another row.

There are two basic groups of flow chart logic, the direct one Flow table logic and the pre-excitation flow table logic. The selected component (transistor, Superconductors, photology, etc.) generally determines the group, although certain Components in both the direct flow chart logic and the pre-excitation flow chart logic are effective.

In the case of direct flow table logic, the logical transfer element prepares the flow table while preparing its row and column lines the assigned logical locking element.

In the pre-excitation flow chart logic, there is a single transmission circuit for each row of the flow chart, when a preparatory electric appears Impulse on the associated row line all possible interlocking circuits to pre-excite the flux table to which the stability is to be transferred. the actual selection of the transmission circuit for the transmission of the stability takes place as a result of an electrical pulse on the selected locking element corresponding column line.

Advantageous features of the invention are its symmetry, its two-dimensional Training and standardization on two basic circuits, the transmission and the interlock circuit.

These features enable quick construction because they are preprinted Flow chart logic worksheets are easy to create for any purpose. The designer puts the flow chart and circuit diagram in logical order on a single worksheet represent.

The advantages of symmetry and standardization are very great. One The data processing system can consist entirely of flow table circuits according to the invention being constructed. A model can be made quickly from slow, cheap and easily suppressible Elements such as B. neon photoconductors can be built. This model can be used to determine the performance of a computing device and thus the current Replace used computing device simulators.

The possibility of quickly adapting the devices to a new one Technology is obvious. The conversion only requires development costs new logic transmission and interlocking circuits.

These properties allow inexpensive mass production, since the structure of the basic row and column conductors and the location of the intersections are unchanged for different circuits of the same technology. The flow table logic machine only needs to be programmed for two standard parts per intersection point, transmission and locking elements or skipping the intersection. With the only one fundamentally changing the input connection to another row just look like a ladder.

By standardizing on two circuit elements, the Dramatically reduced costs. Inventory, paperwork and spare parts storage will be Reduced to a minimum, and the designers are free for other tasks.

Further details emerge from the following description and the drawings. Direct flow table logic F i g. 1 - Pushbutton Pulse Generator Flow Chart A simple sequential circuit device is shown, the flow chart of which is shown in FIG. 1 is used to illustrate the various embodiments of the logic transfer and interlocking elements for the flow table. The device is a push-button AB pulse generator. Three mechanically interconnected buttons R (reset), A and B are used, each of which remains depressed after depressing until another button is depressed. Two buttons are always in the upper position, one is always pressed down. It is assumed that the push buttons actuate switches at speeds corresponding to the speed of the associated device.

First, the R button is pressed, thus preparing the device by establishing the stable state R. In operating condition the A button is pressed and the stability is transferred via 1 to (1). Then it will be button B is pressed and the stability is transferred via 2 to (2); and then button A is pressed again and the stability is transferred back to (1) via 1. The A-B operation can then continue until the power source is turned off or until the device is reset by pressing button R.

After a reset, the device must go through an A-B sequence again be set in motion. If button B is pressed during the reset state, so the circuit assumes the steady state (E) and the device generates an error signal. There is a consequence before a further start-up without an error signal "Energy off", "Energy on" and "Reset" required.

Likewise, if the device is reset while it is in stable state (1), and the necessary final stable state (2) except eight is left, the stable state (E) is assumed.

F i g. 2 - Neon Photoconductor Flow Chart Logic This figure illustrates schematically a neon photoconductor embodiment of the device according to the flow chart from F i g. 1. Each photoconductor is a square with the alphanumeric designation its logic shown, the designation for the stable state interlocking is surrounded by a circle.

Power source 201 is connected to series bus 203 via switch 202, which is connected to column conductors 207, 208 and 209 via column switches 204 (R), 205 (A) and 206 (B) . The row conductors 210-214 intersect the column conductors at right angles, and the conductors are insulated from each other. Neon lamps 215-230 connect associated column and row conductors at their intersections. Each neon lamp illuminates when the associated column switch and power switch are closed and the associated row conductor is grounded.

The conductor 210 has a permanent ground connection 232 via the resistor 231. The other end is marked with a diamond 233, which indicates that the conductor ends without connections. Ladders 211 to 214 "hang in the air" because both end in diamonds; Photoconductors 235 to 240, which are opposite the neon lamps 215 to 225, respectively, ground the row conductors assigned to them when they are exposed to light by the assigned neon lamps. Operation The switches 202 and R 204 are closed and thus connect the energy via the neon lamp 215 to the grounded series switch 210. The neon lamp 215 illuminates the transmission photoconductor 235, which grounds the row conductor 211 and thereby energy via the switch R and the column conductor R 207 through neon lamp 216, through row conductor 211, and transmission photoconductor 235 to earth. The transmission photoconductor 235 transmits the steady state from a built-in stable circuit (through the neon lamp 215 and conductor 210 to earth) to the interlocking photoconductor 236. The neon lamp and photoconductor transmission element is simply a switching device that switches on when its neon lamp is energized designated column conductor earths.

The locking photoconductor 236 is immediately after its grounding associated row conductor 211 via the transmission photoconductor 235 effective. the Neon lamp 216 is switched through the circuit via switch R (204), the neon lamp energized to earth via conductor 211 and photoconductor 235. According to her excitement it locks itself via the photoconductor 236 in the grounded state.

Pressing button A triggers button R and directs current through conductor A 208 to energize neon lamp 217. The buttons can be follow-up contacts, but this is not necessary since the remanent delay of the R-photoconductor is sufficient to maintain the grounding of the conductor 211 until the neon lamp 217 in the transmission element 1 lights up. When energized, the neon lamp 217 illuminates the transmission photoconductor 237, which grounds the row conductor 212 and establishes a circuit for energizing the neon lamp 218 in the locking element 1. The neon lamp 218 illuminates the locking photoconductor 238 and locks it in the steady ON state, thereby maintaining the ground potential on the row conductor 212.

Pressing button B triggers button A and current is passed through column conductor B 209 to energize neon lamp 219; this illuminates the transmission photoconductor 239, which grounds the row conductor 213 and sets up a circuit for exciting the neon lamp 220 in the transmission element 2. The neon lamp 220 illuminates the photoconductor 240 in the transmission element 2 and locks it in the stable state, as a result of which the nominal earth potential on the series conductor 213 is maintained.

When button A is pressed, button B is triggered and power is applied to column conductor A 208 to energize neon lamp 221 in transmitter 1. The neon lamp 221 illuminates the photoconductor 241, which grounds the row conductor 212 and sets up a circuit for energizing the neon lamp 218 in the locking element 1. The neon lamp 218 illuminates the photoconductor 238, which causes the locking in the stable state 1, so that the ground potential at the row conductor 212 is maintained. It is therefore permissible to press the buttons in the order ABAB. Output signals can be taken from the various neon lamps via photoconductors (not shown) or by a meter on the appropriate row conductor; visual observation of the neon lamps is also possible. It is not permissible to initiate the sequence with a B-pulse. Therefore, if the B key 206 is pressed during R, the stable state is transmitted via the transmission element E to the locking element E, which is via the photoconductor 245 to the row conductor 214, via the neon lamp 225, the column conductor 209, the column bus 203, the switch 202 and the power source 201 locked to earth. The transmission element E consists of the neon lamp 224 and the photoconductor 244; the locking element E consists of the neon lamp 225 and the photoconductor 245. The neon lamp 225 indicates an error until the entire device is switched off by the switch 202, after which a reset is required to resume operation.

It is also not permissible to end a sequence with an A-pulse, to which no subsequent B-pulse is assigned. That from the neon lamp 247 and that Photoconductor 248 existing transmission element E grounds series switch 214 when the Button R is pressed after button A to operate the transmission element E.

Abstract neon lamp - photoconductor Made up of neon lamp and photoconductor existing locking element comprises a neon lamp as an actuating device for a photoconductor. A potential is used to set the locking element to the column electrode of the neon lamp and at the same time earth potential to the row electrode placed on the neon lamp, whereupon the neon lamp actuates the photoconductor assigned to it. The photoconductor of the locking element holds the row electrode when it is illuminated the neon lamp to earth potential and thereby causes the locking.

The transmission element also includes an actuating device Serving neon lamp and a photoconductor operated by it. To initiate a transfer operation is performed during a steady state to the column electrode a potential is applied to the neon lamp, while the row electrode of the neon lamp is applied is grounded, whereupon the neon lamp actuates the photoconductor assigned to it. Of the The photoconductor of the input element applies ground potential when it is illuminated Row conductors, usually resulting in the ignition of an interlocking neon lamp at the intersection the row conductor column, which also contains the transmission neon lamp which the transmission photoconductor is connected, leads.

F i g. 3 - Scheme of a circuit derived from a flow chart Since there are only two components, the transmission element and the locking element, you can People familiar with the flow chart itself, the direct flow chart logic easily to understand. The commonly used symbol that is used in river charts for identification steady state is used is a circle 351 which is the alphanumeric Description of the historical step concerned. Hence represents a circle represents the locking element, and the step is indicated by a designation contained therein shown. The transmission element is shown as a triangle 352 pointing to the right. Since the connection for a locking element is always the same, the connection here not shown in the schematic representation. The connection of the transmission element is a line 353 extending from the apex of the triangle and in a small one Arrow 354 ends at row conductor 355.

Diamonds 356 represent electrically loose ends of conductors; dashed Circles 357 represent terminals to which the actuation signals for the flow chart logic to be used components are supplied. The dashed lines are merely Boundaries that sometimes help to resemble a river chart drawing allow.

The actual construction of the circuit can be most advantageous on a flow chart logic diagram with preprinted locations for logic elements working out. The designer prepares a flow chart and draws the transmission and locking connections.

F i g. 4 - Flow table for combination lock A combination lock is a sequential circuit, the states of which can be displayed in a flow chart. The first digit becomes "history" when set; the second digit is based on the correct "prehistory" and becomes "history"; the third digit is based on the correct "history" and means unlocking.

To switch an opto-electronic combination lock with six pushbuttons A to F, which unlock when the buttons are pressed in the sequence ACE, each button being triggered before the next is pressed, a flow table is set up as follows: There are six possible Key selections in each "historical"step; therefore the flow chart has seven columns of blocks, one for the starting position (no key) and one each for the six keys A to F. The number of historical steps does not need to be calculated, since it is inevitable when the flow chart is drawn up results. There are the following historical steps: Historic steps unstable stable key pressed States states (H) N (initial position) 1 (1) A. 2 (2) N. 3 (3) C. 4 (4) 5 (5) E. (6) unlocked There is a stable state for the starting position (no buttons - no "story"), which is shown in FIGS. 4 and 5 is denoted by H. When button A is pressed, switching function 1 takes place, through which the stable state is immediately shifted to (1) for the remaining time in which A is pressed. The "historical" step 1 remains as long as the A key is pressed. If key A can return, the "No key" column takes effect, and 2 transfers the stable state to (2) for the period in which no key is pressed. When C is pressed, the stable state is transferred via 3 to (3). When C is released, the stable state is transferred via 4 to (4). When E is pressed, the stable state is transferred via 5 to (5). When E is released, the stable state is transferred to (6). A 6 is unnecessary because (6) should be stabilized when (5) becomes stable. This corresponds to the principles of merging explained by C a 1 dw e 11.

F i g. 5 - Scheme of the combination lock. The flow table of FIG. 4 is reduced to the schematic form, with circles stable states (interlocking circuit) and triangles represent unstable states (transmission circuit).

The transmission links are also shown. The power supply circuits are not shown because the choice of components has not yet been made. From there Fluorescent lamps and photoconductors make existing flow board circuits convenient and economical the barrier is made from the ones described above, from neon lamps and photoconductors existing transmission and locking blocks.

F i g. 6 and 7 - combination barrier containing neon lamps and photoconductors Interlock circuits consisting of neon lamps and photoconductors are inserted into the with (H), (1), (2), (3), (4), (5) and (6) designated points of the FIG. 5; drawn.

Step 1. The designer simply draws the connections for the extraction elements as shown in FIG. 6 are shown.

Step 2. Switch transmission circuits consisting of neon lamps and photoconductors are drawn in positions 1, 2, 3, 4, 5 and 6, which are the transfer arrows in Fig. 5 correspond. The transmission links to the row conductors that connected to the appropriate interlocking circuits then the flow table logic of the part of the combination lock used for unlocking.

The circuit is also implemented in two steps. In step 1 all locking connections are made (FIG. 6); in step 2 all transmission links established (Fig. 7). Finally, the input, Switching and output devices connected.

Power supply lines are needed to make conductive connections from the earth out through the input or withdrawal photoconductor, via the row conductor 751 through 757, through the entry or exit neon lamps via the column conductors 758 to 764, by pressing the key switch to the non-earthed side of the power source 771 to manufacture.

The unlocking device shown is actuated by a simple excitation coil 772 which is in series with the power source 771 and the series line 756 and can be grounded under the control of the neon lamp in the locking element 6 through the photoconductor in the locking element 6. The switch 773 opens the supply circuit when the door provided with the combination lock is opened; when the door is closed again, the locking circuit is not in a stable state. Then a stable state is created in the take-out H-element by briefly grounding the row line 751 via the reset switch 774, which is located within the room secured by the door and lock.

F i g. 8 and 9 - Flow table and scheme for a combination lock with alarm device There are safeguards against incorrect operation for the combination lock (e.g. by pressing two buttons at the same time) and against approach procedures necessary. Therefore, it is desirable to build an alarm device that is compatible with the Unlocking device from FIG. 7 (flow chart F i g. 4) interacts. As a worksheet the unlock flow chart of FIG. 4 used.

It is desirable to trigger the alarm device if the unlocking sequence is interrupted or if several buttons are pressed at the same time. Since the depression of any key other than the A key in step H is an interruption, each of the remaining blocks 7, 8, 9, 10 and 11 in the row H is assigned unstable condition numbers (FIG. 8). Each of these unstable states must transfer the stability to the alarm series in which stable functions (7), (8), (9), (10) and (11) appear in the columns corresponding to their designation. Step 1 is the stable state for correctly pressing key A. If another key is pressed in step, the stable state must be transmitted to the 757 alarm series conductor immediately. Step 2 is the stable state after correctly pressing and releasing key A. In step (2), pressing any key with the exception of key C is an interruption. The alarm stability states (7), (9), (10) and (11) are ready to accept the transmitted stability should the B, D, E or F keys be pressed; therefore the unstable states are labeled 7, 9, 10 and 11. Pressing key A is also an interruption; the stable state (12) and the unstable state 12 are provided for the alarm in this case. All remaining blocks in flow table rows 3, 4 and 6 (unlocking) are marked with the designation for unstable states in order to transfer the stable state to the alarm series. A final stable alarm condition (A) is provided in the "No button" column in order to maintain the alarm stability uninterruptedly until the door is opened from the inside.

F i g. 10 and 11 - circuit arrangement of a combination lock with Alarm device F i g. 10 illustrates step 1 of the circuit realization, wherein the latch circuits 7, 8, 9, 10, 11, 12 and A are in the circuit of FIG F i g. 7 must be switched on. F i g. 11 shows step 2 where the input circuits of the flow chart logic, which fill in all remaining blocks, to row conductor 757 can be connected and thus complete the combination lock with alarm device.

The alarm excitation coil 1175 actuates the bolt 1176, which opens the door without Considering whether the unlock sequence was complete to the unlock coil 772 to excite, holds locked. The alarm device is by manual triggering the bolt and door unlocking operation and opening the door resettable, whereby the switch 773 is open will. If necessary, power amplifiers can be used be inserted into the excitation coil circuits.

Claims (7)

Claims: 1. Sequential circuit, its successive switching states can be displayed in the known flow table, characterized in that each column a column conductor corresponds to the flow table and a row conductor corresponds to each row of the flow table, that the input signals are fed to the column conductors, that the output signals derived from the switching states of the row conductors that on the stable Crossing points of column and row conductors corresponding to the states of the flow table Interlocking circuits are provided, which each connected row conductor keep prepared as long as the connected column conductor is excited, and that at the unstable states of the flow table, corresponding crossing points the column and row conductors transmission circuits are provided, which the preparatory state of the row conductor connected to it to one or more row conductors transmitted when the column conductor connected to the transmission circuit is energized is. 2. Sequence circuit according to claim 1, characterized in that the row conductors are connected to ground in the prepared state. 3. Sequential circuit according to claim 1 or 2, characterized in that the column conductor is optionally via switches can be connected to a power source. 4. Sequential circuit according to one of the claims 1 to 3, characterized in that between one prepared in the end switching state Series conductor and a power source an excitation coil for triggering a control function is provided. 5. Sequential circuit according to one of claims 1 to 4, characterized in that that the latch circuit consists of an electric light source between the column conductor and the row conductor is switched on, and that in the radiation area the electrical light source, a photoconductor is provided, the associated Keeps row ladder prepared, e.g. B. connects to ground. 6. Sequential switching to one of claims 1 to 5, characterized in that the transmission circuit consists of an electric light source placed between a column conductor and a row conductor is switched on, and that in the radiation range of this light source a photoconductor is provided which has the associated latch circuit connected row ladder prepared, z. B. to ground. 7. Sequential switching to one of claims 5 and 6, characterized in that the electric light source a neon lamp is provided. B. sequential circuit according to one of claims 5 to 7, characterized in that the output signals from one or more electrical Light sources are triggered. Publications considered: Österreichische U.S. Patent No. 209,599; "RCA Review", December 1959, pp. 715 to 743; “Arithmetic Operations in Digital Computers ”, D. van Nostrand, 1955, p. 338; “Proc. Cambridge Philos. Soc. ”, Vol. 49, 1953, pp. 230-238.