DE2802160A1 - Time buffer device for incoming series bit trains - has writing and reading store controlling number of signal stores - Google Patents

Abstract

The bit trains are stored in one or several signal stores, and collected from the store(s) in the same order as they were stored. One single writing-reading store (32) is provided for several independent and asynchronously operating signal stores. It has storage locations for information storage (IS) and further storage locations for determination of position of a newly arrived signal, and the position of a signal to be read out. When a signal is to be written, its position differs by one from that of a signal to be read out. When a signal is read out the position of the next signal to be read out is nearer by at least one to the position of a signal to be written in. When operating any of the available stores, the writing-reading store (32) applies the address of the respective store and connects its last state to its outputs connected to the inputs of an intermediate store (33). This state is stored in it on reception of a pulse at its transfer input (E), and switched to its outputs.

Description

Device for temporal buffering of serially incoming

Bit strings in one or more silo memories The invention relates to a device for temporal buffering of serially arriving bit sequences in one or several silo storage facilities in which the

information entered into the silo in the order of Entries in the respective silo memory can be removed again.

When transmitting information, it is often necessary to to buffer serial bit sequences in time, i.e. these bit sequences with a specified Enter speed in a memory, in this to save a certain time and then from this memory again mostly at a speed compared to the input speed read out at greater speed. The so-called fast FIF0 registers (first - in - first - out - register), where the sequence the output is the same as the order of the input. Such FiFO register memories are also referred to as silo storage, because they, like a silo, have a The information entered is brought to the last free space as soon as it is entered wna not, as with a shift register, only when one arrives new information is pushed on and the last digit of the register only reached after a number of steps. The first information is thus immediate brought to the output of the memory. The following information comes up to the first piece of information so that the store is filled up like a silo. Disadvantageous is the fact that these known fast FIS0 registers are used for short bit lengths are uneconomical and mostly have bit-parallel inputs, which however do not independently, but can only be operated together.

This disadvantage can be eliminated by using computers with which independent FI # O functions can be carried out using programs in the working memory (Read / write memory) of the computer. But this solution points the disadvantage that the data manipulations to control the FIF0 function very are time consuming because they require a series of commands to handle.

The aim of the invention is to take advantage of the fast FIF0 registers to combine with the advantages of facilities that work with computers and to achieve fast, Independent #IFO functions economically, if possible through a single central office To be able to implement control as well as the disadvantages of the known solutions such as inefficiency, larger space requirements and greater expenditure of time to avoid.

According to the invention, this is done in a device mentioned at the beginning achieved in that for several independently and asynchronously working silo storage a single read-write memory is provided, which both memory elements for Storage of the information as well as other storage elements for determining ir Position of a newly registered character as well as the position of the character to be read out, where each Sign the place of the new to be registered Character removed from the position of the character to be read out by one and when reading out With the new character the position of the next character to be read out of the position of the newly to be written character approaches by at least one, and that the read-write memory in the event of a manipulation of any of the available silo stores after the address has been created of the silo memory concerned switches the last state of the same to its outputs, which are connected to the inputs of a downstream buffer store, in which this last state is stored after a pulse at its takeover input and is switched through to its outputs. The read-write memory (random-access-memory), also called RAM for short, is used purely as a data memory. The function of the FIF0 memory is saved by additionally storing the address of the next value to be entered or the value to be read out next. The when using calculators Required sequential treatments are thereby carried out by static networks short lead time replaced.

A particular advantage of the device according to the invention lies in the use of cheap integrated memory circuits, which are supported by a simple, A highly beneficial external logic converted into multiple silo storage can be.

Surprisingly, for the first time there was also the simple possibility of the reading out of all silo memories automatically only from a certain freely programmable To allow filling level, which was previously only possible with a complex control logic was, the ongoing balance of all written and read information bits had to lead.

Advantageously, there are outputs that carry the information of the buffer store both masking gates and A-: ti ## inputs of a multiplexer connected and the location of the next to be registered or

to be read out at outputs of the buffer memory Inputs from read-only memories, each one of the number of information bits have a corresponding number of masking outputs connected in parallel and are fed to the masking gates, the best value memories as a function of each are released or saved by a write or read command, and where the read-only memory further characterizing the position of the new bit to be written Have outputs that are also connected in parallel to inputs of the multiplexer are connected, the outputs of the masking gates via an intermediate multiplexer are connected to other B inputs of the multiplexer, its the location of the new the bits to be written and the outputs supplying the information together with other parallel-connected, the position of the new bits to be read out Characteristic outputs of the read-only memory to the data inputs of the read-write memory are returned.

With this measure, a particularly space-saving, relatively cheap and all requirements satisfying equipment achieved.

Further details of the invention emerge from the drawing, in which, among other things, an exemplary embodiment is shown.

Zig.? shows a known system for the transmission of information between several typewriters, Fig.2 one of the stations of a system for information transmission between several typewriters with a device according to the invention, Pig.3 an example of storage according to the invention in a cell of a read-write memory with 15 bit each 8 bit silo memory and Pig.4 the scheme of a read-write memory with a 3 bit silo memory, with 2 bit for the place of the new one to be written in Character identifying signal, with 2 bits for the place of the character to be read out and 1 bit for the read enable signal. FIGS. 5 to 9 show the state and the function of the memory cells and FIG. 10 shows a particularly advantageous circuit arrangement for the device according to the invention.

In the example shown in Figure 1 of a known system for The transmission of information is the outputs from typewriters 1 to the inputs connected by silo storage 2, which are each controlled by a control unit 3. The outputs of the silo storage 2 lead to the inputs of a common transmission side Multiplexer 4, which is advanced by a clock 5. At the output of the multiplexer 4, the data or information taken from the silo memories 2 are sent serially the transmission path 6 laid, at the end of which a receiving-side demultiplexer 7 lies. The outputs of the demultiplexer 7 advanced by the clock generator 8 are present to one decoding memory 9 each, which are controlled by control units 10 and at the outputs of the inputs of typewriters 11 are, of which those of the information supplied to the typewriters 1 is written down. The exits the typewriters 11 are also located at the entrances of silo stores 12, which are controlled by control units 13 and their outputs to a multiplexer 14, which is advanced by a clock 15.

The output of the multiplexer 14 leads via the transmission path 16 to a demultiplexer 18 which is advanced by the clock generator 17 and whose outputs are connected to Decoding memories 19 are located, the outputs of which to the receiving inputs of the typewriters 1 and which are controlled by control units 20.

In the known system shown in Figure 1, the can of the Typewriters 1 and 11 sent out Information in the silo stores 2 or 12 regardless of when the transmission via transmission path 6 or 12 takes place, are stored. The stored in the silo memories can also be used Information read out regardless of the input time and input speed will. The information can thus be sent from the typewriters 1 or 11 to each any time and at any speed and regardless of the Work of the other typewriters to be written into the silo storage where the information is stored in the same order as it is entered will. With the multiplexers + or 12, the stored information of the Read out one after the other from the silo memories 2 and transferred to the opposite station will. It can be seen that with such a system the readout speed and thus the frequency of the bits read out can also be selected higher than that Input speed or input frequency, including the input speeds or the frequencies of the individual typewriters can differ from one another. In essence, an effect similar to that achieved with use is thus achieved was achieved by punched tape transmitters.

As stated at the outset, such a known system has i.a. the disadvantage of the need for a large number of silo memories with decoding memories with the associated control units, is therefore expensive and takes up a lot of space.

The disadvantages of the known system shown in Fig.1 become avoided in the system shown in Figure 2 with a device according to the invention, in which the outputs of the typewriters 1 are sent directly to a multiplexer 20 are connected, the output of which is connected to the information input A of a silo storage unit 21 is performed, the output B of which is the information to be transmitted via the transmission path 6 can be taken. The silo storage unit 21 is made by a single control unit 22 controlled, two clocks 23,24 are indicated.

The clock 23 determines the speed of writing the information supplied by the multiplexer 20 into the silo storage unit 21, the Clock 24 the speed of reading out the data in the silo storage unit 21 stored information. The control unit has an output C, which is both to the multiplexer 20 as well as to the silo storage unit 21 the address of the assigned Silo storage supplies, and an output D, which takes over to the silo storage signal delivers. The control unit 22 continuously supplies all addresses to the output C. for the cells of the silo storage both at these and at the multiplexer 20, via which, depending on the address, the individual typewriters 1 to the Information input A of the silo storage tank can be connected. The control unit has further control outputs E, F, G, H, which are explained in more detail with reference to FIG will.

The transmission path 6 does not lead to the receiving side in Figure 2 opposite station shown, which is constructed analogously to the station shown in Fig.2 is.

The output of the silo storage unit of the opposite station leads via the Transmission path 16 to the input of a silo storage unit 25 of the one shown in FIG Station. The silo storage unit 25 is completely analogous to the silo storage unit 21 and is connected to the outputs 0, D, E, F, G, H of a control unit 26 via control lines connected, which is also analogous to the control unit 22 and of clock generators 27.28 is clocked, but here the control speed for writing information is generally larger than that for reading since reading out the silo storage unit 25 takes place via a decoder memory 29, the outputs of which are connected to the receiving inputs of the typewriters 1. There are those Address outputs a of the control unit 26 to both the Silo storage unit 25 and connected to the decoding memory 29, via which the output B the silo storage unit 25 lying information sequentially to the receiving inputs the typewriters 1 are placed.

The measure according to the invention is that in the silo storage unit 21 or 25 for several independently and asynchronously working silo storage units Read-write memory (RAM) is provided, which both memory elements for storage the information as well as other storage elements for determining the location of a to be rewritten as well as the location of the character to be read out, wherein When registered, each character takes the place of the new character to be registered away from the position of the character to be read out by one and when reading out each Character the position of the next character to be read out of the position of the new one to be entered Character approaches at one. This is explained with reference to FIG.

3 shows a cell of a read-write memory with an 8-bit silo memory in the case of binary coding of the character indicating the position of the new character to be written, briefly referred to as input pointer EZ signal and the point of the to be read Character indicating signal, referred to as output pointer AZ for short. With IS is the information memory of the silo memory with 8 bits, with LF the read release delivering signal designated with 1 bit. The cell of the read # write memory has in this example 15 bits.

In the silo memory are shown with the arrow 30 cyclically Corresponding to the write / read direction, the information is entered for temporary buffering. This information is also back in the direction of the arrows. 30 read out. the The input pointer EZ (bit 8 to 10) and the output pointer iz (bit 11 to 13) are used the creation of the silo memory effect and are for every information store IS available separately. The s.B.

binary coded content of bits 8 to 10 is interpreted as an address and thus points to a cell of the information memory into which the next incoming Information bit is to be entered. Regardless of this, the content of bits 11 to 13 to the character of the information memory IS to be read out next. Became If a character is entered in the information memory IS, the value of the Input pointer EZ increased by one and thus points to the next cell. Corresponding applies to the output pointer AZ, except that this is first increased by one and gradually Check whether it has not yet caught up with the input pointer EZ, releases it for reading. Should the entrance pointer EZ have been caught and thus to a cell point that does not yet contain any information, the value of the output pointer AZ again decreased by one.

The silo memory is reported as emptied, the read release (Bit 14) is blocked. The last valid value can be read out if necessary.

If a new bit is written in, the readout is then carried out again enabled (bit 14 set).

By simply delaying the setting of the read enable XF by one constant amount is achieved that the readout from the silo memory only starts takes place at a certain level. It is also monitored that the input pointer EZ cannot overtake the output pointer AZ. The output pointer AZ becomes the input pointer EZ overtaken, the silo storage is reported as full and the registered mail prevented.

4 shows the diagram of a read / write memory with a third bit information memory IS (bit O to 2), a 2-bit input pointer EZ (bit 3 and 4), a 2-bit output pointer AZ (bits 5 and 6) and 1 bit for the read enable LF (Bit 7) shown for each silo storage tank.

There is therefore an 8 bit under each address of the read / write memory Word stored that contains all the elements required for the memory function.

The function of a memory cell will now be based on FIGS of the read-write memory, in which the arrow 31 indicates the read-write direction indicates. The commands that bring about the various functions can, for example are supplied by the control unit 22 shown in FIG.

For example, the commands can read or "write" at the output G and the command 'set read release' at output P of control unit 22 will.

5 shows the function of a memory cell with the "read" command. The output pointer AZ points to the location na of the information memory IS at which a logical pl stands. The location hF of the memory cell intended for the read release has a logical ld and corresponds to the idle state. When reading is going on the logical t§ ~ "is output to which the output pointer AZ points.

6 shows the function of the memory cell in the case of the "write" command. At input A (Fig. 2), for example, there is a logical In, which is at position 1 of the information memory IS is written. The input pointer EZ is increased and points to position 2 of the information memory IS. Since at the point LP for the read release is a logical nan, the output @@@ pointer AZ cannot move forward and therefore still reads the information "#" located at the position IS = #.

7 shows the function of the memory cell in the case of the "read release" command by which a logical "1" is placed in place LP. The storage cell is prepared for reading.

FIG. 8 shows the function of the memory cell with the command "Read. Da If there is a logical ~ 1 "at the point LF for the read release, the output pointer becomes AZ increases and now points to point 1 of the information memory IS at which a logical ~ 1 "is stored.

As the output pointer AZ points to another location in the information store IS points as the input pointer EZ, which is at position 1 of the information memory IS stored logic 11111 read out.

In general, the memory is controlled by the control unit 22 in such a way that that, depending on the clock generator 23,24, write-read cycles follow alternately. If, after the situation shown in Fig. 8, another read command would follow, without any new information having been written in beforehand, this would result a process which is shown in Fig.9.

Since in the situation according to Figure 8 at the point LF for the read release If there is a logical "1", the output pointer AZ is incremented and points to the position 2 of the information memory IS, where an In is entered, which indicates that this Place has no content yet, which is indicated by the input pointer EZ points to this point in the information memory IS and indicates that this point is empty, so information has to be written in first. The position EF of the Read release is set to ß "and the output pointer hZ is reduced by one, see above that he points back to the point 1 of the information memory IS, where a logical "1" is located, which is thus read out. It is now, as shown in FIG outlined, the logical "1" is continuously read out.

So if a logical npln then the output pointer AZ is not moved any further when reading, which is only done by the This is the case when there is a logical "1" at the point LP. if themselves with the command "read" there is a logical "1" at the point LF and when moving forward the output pointer AZ would point to the same position as the input pointer EZ, the output pointer AZ remains in place and the read release LF is automatically set to pl.

In Fig.10 is an embodiment of a device according to the invention for the silo storage unit 22,25 shown in Figure 2, in which the based on the Figures 5 to 9 implemented sequences shown by a purely static network will. The characters for the information IS, the input pointer EZ, the output pointer AZ and the read release LF as well as for all further connections for the sake of simplicity, only individual connection paths are drawn. In the practical Implementation is the number of required connection routes through the choice of Ooding determined. When choosing a read-write memory according to the scheme according to Fig. 4 For example, there would be three connection paths for the information store, for the Input and output pointer EZ, AZ Two connection paths each and for the Read release LP a connection path required.

In accordance with FIG. 2, the silo storage unit shown in FIG input A for the information to be written in, output B for the information that has been read out Information, the input C for the address to the read / write memory, the input D for the takeover command to the read / write memory 32, the input E for the Takeover command to buffer 33, input P for the set command ~ read release ", the input G for the read / write command and the input H for the initial loading of the Charge nultiplexer 34.

The read / write memory 32 can, for example, be an RLM with 64 x 8 bit, with which 64 silo memory for 3 bit each Information, 2 bit input pointer, 2 bit output pointer and 1 bit read enable, whereby the respective memory with a 6 bit address can be selected.

The outputs IS of the read / write memory 32 for the information EZ for the input pointer, AZ for the output pointer and LF for the read enable lead to the buffer 33, at the outputs of IS, EZ, AZ and IS in one for the input E given takeover command the output from the read / write memory 32 Data are placed.

The outputs IS of the buffer 33 lead on the one hand to A inputs a multiplexer 35, on the other hand to a nasking network, which is shown in FIG. 10 for the sake of simplicity is represented by an AND gate 36 and an OD3R gate 37 for the sake of purpose. The exits EZ for the input pointer and AZ for the output pointer are with the inputs EZ, AZ of a read-only memory 38 and a best value memory 39 connected. The exit LF for the read release of the intermediate memory 33 leads both to the J? Estwertspei cher 39 and to an input of the multiplexer 35, the output EZ for the input pointer also to A inputs of the multiplexer 35. The read-only memory 38 has an information input INS, which is connected to the information input A of the silo storage unit, to which the information to be written is placed, which moreover becomes a Read-write multiplexer 40 are performed. The control of the read-only memory 38,39 and the read-write multiplexer 40 is carried out by a read-write command from Input G here, which is connected to the read / write multiplexer 40 and the best value memory 39 directly to the test value memory 38 via an inverter 41: #losSen is. The western value memory 38 joins with a write command, the X measured value memory 39 a read command in function. Both kest value memories 38,39 have masking outputs M on that lead to the masking gates 36,37, the outputs of which at the inputs of an intermediate multiplexer 42 whose control input #it the y1 output of the read-write nultiplexer 40 is connected. The outputs ore '(input pointer) the two read-only memories 38, 39 are connected in parallel to further B inputs of the multiplexer 35, whereas the outputs AZ '(output pointer) on the one hand to the inputs AZ' of the load multiplexer 34, on the other hand to the inputs AZ 'of a read multiplexer 43 are connected, the output of which forms output B of the silo storage unit and its data inputs IS 'are connected to the y1 outputs of the swlultiplexer 35 which are also connected to the IS 'inputs of the loading multiplexer 34 stand. The input pointer which can be passed on via the y2 outputs of the multiplexer 35 EZ 'the read-only memories 38, 39 are connected to the loading multiplexer 34 via the EZ' inputs feedable. The outputs LF of the buffer memory that are present at the inputs Bg 33 read / release characters are transferred via output y3 to input B2 of the read / write multiplexer 40 is supplied.

The multiplexer 35 is controlled via an AND gate 44, its one input to the input F of the silo storage unit that accepts the set command and its other input with the input taking over the read / write command G of the silo storage unit is connected, which is also connected to the control input of the read-write nultiplexer 40 leads. The output LF 'of the read-only memory which transmits the read enable character 39 is connected to an input of the read / write multiplexer 40. At the control entrance of the loading multiplexer 34 is the input H of the silo storage unit.

For a better understanding of the function of the silo storage unit The following example shows the truth table for the assignment of the control inputs That The character "x" means that the assignment is arbitrary.

To control the read-write processes, the following, more and more constant, from the control unit 22 or 26 (Fig.2) brought about the sequence apply.

In the idle state there is, for example, the takeover input D of the read / write memory 32 the command ~ Read ", at address input C one of the addresses for the read / write memory 32 and at the read / write input G one of the functions according to the truth table above. The transfer input E for the buffer 33 is activated. If at the read / write input G the command ~ Read "is present, then at output B there is information to be read which can be found here. The transfer input D of the read / write memory 32 is briefly to "write" and then to switch back to the idle state.

In the case of a "bootstrapping" command applied to input H, the read / write memory 32 is brought into a defined position after the power supply is switched on by a specific bit pattern from a read-only memory 45, for example according to FIG. 5 with EZ = IS1, Z = IS ~, IS # = # and IP = 16, placed at the inputs IS, EZ, AZ, LF of the loading multiplexer 34 and via this to the data inputs of the read-write memory 32 and stored at all addresses. FGH Entrance AFGH Function s ~ InformationLF-Set- Write3 "1" nI # = 1 read = "~" flatbread 31 1 write 1 16 1 1 O write 16 16 1 1 PCB setting x 1 1 1 Read xx 16 1 Bootstrap x ~ If a logical ~ 1 "is now to be written, the address of the desired silo memory is created and the stored bit pattern is stored in the buffer 33. By activating the write input A to" 1 ", the read-only memory 38 is enabled via the inverter 41. At the inputs of the The read-only memory 38 contains the old values of the input and output pointers as well as the information that a "1" is to be entered in the read / write memory 32. The read-only memory 38 contains the new values of the for all combinations of the input pointer EZ and the output pointer AZ The AZ values are passed on unchanged. Free outputs of the read-only memory 38 can be used for this purpose.

Depending on the information to be written, "1" or '~ " and the value of the input pointer EZ is at the outputs "M" of the read-only memory 38 a mask is placed on the masking gates 36,37, the AND gates 36 being used for writing a "ß" and the OR gate 37 are used to write an f1. Via the read / write multiplexer 40 is the information "'t' write" to the multiplexer 42, for connection of the result of the masking gate 37 to the multiplexer 35, the multiplexer 35 is controlled via the AND gate 44 with ~ 2 and thus the new value IS 'via the loading multiplexer 34 applies to the inputs of the read / write memory 32.

The value of the load release IF is unchanged from the buffer 33 via the multiplexer 35 (output y3) to the write Leee multiplexer 40 and via this (output y2) placed on the loading nultiplexer 34 and shared with the over the multiplexer 35 coming new value EZ 'of the input pointer of the read-only memory 38 and the unchanged value AZ of the output pointer via the Charging multiplexer 34 applied to the data inputs of the read / write memory 32.

With a short pulse at the read / write input of the read / write memory 32 becomes the new value of the silo memory in the addressed cell of the read / write memory 32 saved.

When issuing the command set read enable ", in contrast for the command "1" -write via the AND gate 44 of the multiplexer 35 to switch through of the A inputs switched so that all bits of IS, EZ and AZ remain unchanged and only LF is set to "1t".

If the read command is issued, the test value memory 39 is released, which, depending on the input LF and the difference EZ - AZ, determines the new value of the Output pointer AZ supplies. A logic "1" is sent to the multiplexer 40 Control input of the intermediate multiplexer 42 applied so that the masking gate 37 is active are. The read-only memory 39 rigidly supplies the mask #, so that IS remains unchanged the multiplexer 42,35 reaches the multiplexer 43,34. In conjunction with the new Address "AB" is sent by the multiplexer 42 to the bit that has been read out at the information output placed. The EZ values are passed on unchanged, which is due to free outputs the read-only memory 39 can be accomplished.

The new values to be written into the read / write memory 32 arrive via the multiplexer 34 to the inputs of the read / write memory 32 and are stored by a short write pulse in the addressed cell of the same.

The invention is not limited to the illustrated embodiment limited. In particular, in place of those shown in FIGS Typewriters will also interfere with any other data transmitter or data receiver.

The capacities of the memories and multiplexers can also be selected as required.

Claims (10)

Claims: Device for temporal buffering of serially incoming Bit sequences in one or more silo memories, in which the silo memory (s) information entered in the order in which it was entered in the respective silo memory can be removed again, characterized in that for several independently and asynchronously working silo memory a single read-write memory (32) is provided, the storage elements for storing the information (IS) as well as others Storage elements to determine the position of a newly enrolled person as well as the Position of the character to be read out, with each character being written the position of the new character to be written in from the position of the character to be read out removed by one and the position of the next to be read out when reading out each new character Character approaches the position of the new character to be inscribed by at least one, and that the read-write memory (32) upon manipulation of any of the available Silo memory after creating the address of the relevant silo memory the last State of the same switches to its outputs, which are connected to the inputs of a downstream Intermediate memory (33) are connected, in which this last state after a pulse stored at its takeover input (E) and switched through to its outputs will. 2. Device according to claim 1, characterized gekennzeionnot that to the the information (IS) carrying outputs of the buffer (33) and masking gates (36, 37) and A inputs of a multiplexer (35) are connected and that the the position of the next bit to be written in or to be read out characterizing the outputs (EZ, AZ) of the buffer (33) to inputs (EZ, AZ) of read-only memories (38,39) are led, each one corresponding to the number of information bits Number of masking outputs (M) connected in parallel and connected to the Masking gates (3ü, 37) are performed, the read-only memories (38,39) each in Enabled or disabled depending on a write or read command (G), and that the read-only memory (38,39) further, the location of the new to be written Bit-identifying outputs (ES '), which are also connected in parallel B inputs of the multiplexer (35) are connected, the outputs of the masking gate (36, 37) via an intermediate multiplexer (42) to further B inputs of the multiplexer (35) are connected, its identifying the position of the new bits to be written and the outputs supplying the information together with other parallel-connected, the position of the outputs (AZ ') of the read-only memory that characterize the new bits to be read out (38,39) are fed back to the data inputs of the read / write memory (32). 3. Device according to claim 2, characterized in that a when Read command releasable read-only memory (39) and one releasable with the write command Read-only memories (38) are provided, with the input (INS) of the write command releasable read-only memory (38) the information to be written (A) is placed and that the line carrying the write or read command is connected to the read command released read-only memory (39) directly to the one released with the write command Feature value memory (38) is connected via an inverter (41). 4. Device according to claim 2 or 3, characterized in that the control input of the multiplexer (35) is connected to the output of an AND gate (44) at whose one input the write or read command (G) and at the other input of which the set command (F) is placed. 5. Device according to one of claims 1 to 4, characterized in that that the output (LF) of the buffer (33) which supplies the read enable signal both to an input of the read-only memory enabled by the read command (39) as well as to a B input of the multiplexer (35) and connected via the at Read command enabled read-only memory (39) to an input of a read-write multiplexer (40), at whose B inputs on the one hand information to be written, on the other hand, the read enable output (y3) of the multiplexer (35) lie. 6. Device according to one of claims 1 to 5, characterized in that that the information supplying outputs of the multiplexer (35) in connection with the outputs of the read-only memory that characterize the position of the bit to be read out (38,39) are led to the inputs of a read multiplexer (43), to its output connected to the transmission path (B) conveying the information that has been read out is. 7. Device according to one of claims 1 to 6, characterized in that that the outputs (y1) leading the information to be written and the position outputs (Y2) of the multiplexer that characterize the new character to be written (35) as well as the outputs characterizing the position of the new character to be read out (y3) and the output (y2) of the read / write nultiplexer that supplies the read release (40) via a load nultiplexer (34) to the data inputs of the read / write memory (32) are connected. 8. device according to one of claims 1 to 7, characterized in that that the address (a) and that Takeover signal (D) to the read / write memory (32), the transfer signal (E) to the buffer (33), the set signal (y) via the AND gate (44) to the multiplexer (35), the write or read signal (G) the AND gate (44) to the multiplexer (35), to the read-only memory (39) the inverter (41) to the read-only memory (38) and to the read / write multiplexer (40) and the charging signal (H) to the charging nultiplexer (34) supplying lines a common control unit (22,26) are connected. 9. Device according to claim 8, characterized in that the the The output of the control unit which supplies the address (o) to the read / write memory (32) (22) is connected to the control input of a data multiplexer (20) whose the output (A) delivering the information to the released by a write command Read-only memory (38) is connected and the information transmitter at its inputs (1) lie. 10. Device according to claim 8, characterized in that the the Address (c) delivering output of the control unit (26) to the control input of a Decoding memory (29) is connected, the data input of which is connected to output (B) the silo storage unit (25) is connected and its outputs with the information receivers (1) are connected.