CH366162A - Electric sorting system for objects - Google Patents

Description

  

      Electrical sorting system for objects The principle of numerical sorting of objects marked with numbers requires the comparison of the numbers according to some guiding principle. The individual comparison process different sets of numbers, which are originally in a random order, can, for. B. be repeated as intermediate results forming, partially ordered sequences until a single ordered sequence (z. B. numbered objects) results, which corresponds to a certain order, the normal order, z. B. increases or decreases in value.



  The simplest comparison process is that between two quantities (numbers). If this principle is followed, the numbers or object numbers of two piles of objects can be compared with one another and the objects are stacked one after the other in two intermediate stacks in groups, which groups obey the order in front of them. The individual items in these groups can then be subjected to the same comparison process again, group after group, until the result of the sorting is only the normal order.



  The cited principle of sorting is more detailed in the 22nd lecture titled Sorting and Collating by Mauchly and partly in the III. Volume of Theory and Techniques for Design of Electronic Digital Computers from the Moore School of Electrical Engineering, University of Pensilvania, June 30, 1948.



  If the indicated principle is to be used to form a single sequence from a group of numbers with an arbitrary distribution in successive sorting processes, it is not entirely satisfactory. Indeed, this principle of comparison requires that a number of <I> N </I> numbers log, <I> N </I> has to be treated, e.g. B. seven times if N = 100 (or 128). Exactly the same number of sorting processes is necessary if the N numbers happen to appear in the desired or the opposite order.



  In the book by R. K. Richards, entitled Arithmetical Operations in Digital Computers, pages 296 to 299, another method of sorting by comparison is given. This has the advantage that any random number distribution can be used for comparison.



  The latter method requires the use of two input stacks <I> A, B </I> and from two output stacks <I> C, D </I> (Fig. 1). If it is assumed that the desired order, i.e. the normal order, increases from smaller to larger values, the numbers A1, B1 become the first objects of the two input stacks <I> A, B </I> compared and the object with the smaller of the two numbers - be it A 1 - must match the one of the output stacks, e.g. B. C cite. A 1 now becomes the number Cl.

   After this initial comparison of two numbers <I> Al, B1 </I> now takes place as long as there are still objects on the stacks <I> A, B </I> are present, a comparison of three numbers, namely of <I> A, B </I> from the input stack and from C as the last number moved. For the sake of simplicity, the following briefly refers to the change in position of the objects provided with numbers as the change in position of their numbers. The stacks are also known as lists.

   After the initial comparison, the second number A2 from the input list A, which delivered the first number C1 to the output list C, is compared with the first number Bi of the other input list B and also with the number C1. If <b> <U> A ,. </U> </B> and Bi are both larger or smaller than C1, the smaller of the two numbers A2, Bi is either given as the second number to output C, if A2, Bi are larger than C1, or passed to the other output D to this output to cite

   if A2, Bi are less than Cl. But if A2 or Bi is greater than Cl, the larger of the two numbers A2, B1 is moved to the list C already started by C1 as the second. The offset number <I> A </I> or <I> B </I> is replaced by a new number from that input list A, B from which it came: This comparison of three numbers is continued until one input stack is empty. Then the final comparisons are made with two numbers.

   If the new number is larger than the one previously moved, it follows it on the same starting pile; if it is smaller, it is placed on the other starting pile. The two outgoing lists are now used as incoming lists for another sorting of the same type (second sorting level). After only a single list (batch C or D) is received at the end of a sort stage; the sorting process is finished and all numbers are in the desired order.



  The main purpose of the invention is to create an electrical sorting system which allows the above-mentioned known principle to be carried out in practice.



  Accordingly, the invention creates an electrical sorting system for objects in which the numbers displayed in an electrically perceptible manner on the latter are sorted by dual comparison processes, with a pair of initially randomly ordered sequences of objects in several work processes in a new pair of differently ordered sequences is transferred and a comparison process extends to at least two items, each of which is removed from a different original sequence, which system is characterized in that two electrical shift registers with at least n + 1 stages are provided, where n is the number of binary Is digits needed to identify any of the numbers that the two registers are used to

   to register the number of an object from the first or second original sequence, so that when a new number from one of the original number sequences is progressively introduced into one of the registers, it is compared digit by digit with the number contained in this Register was previously stored and the progressively exits from said register that said new number, while it is being introduced into said register, is simultaneously compared digit by digit with the number previously stored in the other register and which circulates continuously through this, and that means are available which register the order of the relative size of the numbers as a result of the comparison,

   and that, depending on this sequence, one of the objects is supplied with one of the new sequences, after which the aforementioned comparison process is repeated analogously when an object is supplied from an original sequence until an original sequence is processed. The following is the description of a Ausführungsbei game of the invention with reference to the drawing.

   In this, FIG. 1 shows the scheme of the processes in a sorting stage, FIG. 1a shows a table for sorting processes, FIG. 2 shows the electronic circuits which compare the numbers that are entered on the documents to be sorted, FIG. 3 electrical control circuits which cooperate with those of FIG. 2, FIG. 4 shows the pulses which appear at some terminals, FIG. 5 shows the comparison circuit CP, which is shown as a block in FIG. 2, FIG. 6 shows the comparison circuit CPC, the 5 is shown as a rectangle in FIG. 7 and FIG. 7 shows the manner in which FIGS. 2 and 3 are to be put together.



  Fig. 1 shows a diagram that is used for the detailed explanation of the already briefly outlined Sor animal processes, which are to be controlled by the electrical circuits to be described later.



  In Fig. 1, seven positions are shown as rectangles; in the first two positions <I> A </I> and <I> B </I> arrive the numbered documents (objects) to be sorted from document memories (not shown). If the first document from the first memory is in the A position and if at the same time the first document from the second memory is in the B position, the document in the A position can be in an intermediate position A 'or the document in B Position in the intermediate position B '.

   Between positions A and <I> A ' </I> as well as between positions B and <I> B ' </I> reading devices (not shown) are installed, which are arranged in such a way that when the numbered documents are along the path between the positions concerned <b> <I> A -A ', </I> </B> B-B 'move, the characteristic number (number) of the document, which determines how the document should be sorted, analyzed and a record of this analysis is made.



  If two documents have the corresponding positions <I> A ' </I> and <I> B ' </I> (Intermediate Positions) after their numbers have been read, an electrical comparison circuit is able to determine which document has the lower number.



  If it is assumed that the sorting process is such that the final sorting should leave the documents in ascending order, with the lowest numbered document going ahead and the highest numbered document being the last, the first sorting process (initial comparison of two numbers) will make the document lower Number in position <I> A ' </I> or <I> B 'to </I> the point position <I> H </I> moved while the other document remains in the interlayer B 'or in the example in A'. The document moved to H is now replaced from batch A or B. At the same time that the two documents in the intermediate positions A ', B' are compared, a comparison is made between the numbers of these documents and the number of the document which is in the switch position H.

   In this way, three numbers are
EMI0003.0000
  
     Ask in these cases <I> A </I> and <I> B </I> represents the number of the two documents which were moved forward from the A and B positions, while C represents the number of the document which was the last to pass through the H position.



  After the automatic comparison, the document is moved from column 3 to H. When a document reaches the switch position H, the switches are set so that the document is moved either in the direction of the starting position C or in the direction of the starting position D in accordance with the column 5. As soon as the document has the switch position <I> H </I> in the direction of C or <I> D </I> has left, the switches are automatically returned to their normal standby position to pick up the next document either from the intermediate position <I> A ' </I> or from the intermediate position <I> B ' </I> to be received.

   Of these, however, one is now free, which will be filled, namely: if the shifted document came from the intermediate position A ', the intermediate position B' is still occupied by a document, and accordingly the next document, which is the position A ' occupied, come from position A. In the opposite case, it is the document from the B position that is brought into the B 'position.



  According to the preceding explanations relating to FIG. 1, which in conjunction with the table FIG. 1 a serve as a basis for understanding the type of sorting, a whole sorting is to be described with the aid of a numerical example with only eight numbers using FIG.



  It is assumed that the two numerically equal digit sequences 7, 3, 2, 8 (SA) and 5, 6, 4, 1 <I> (SB) </I> are to be sorted in a sorting system according to FIG. 1. The first-mentioned stack 7, 3, 2, 8 is in front of <I> A, </I> or the latter 5, 6, 4, 1 above <I> B. </I> At the beginning of the first sorting stage (Fig. La) of the two successions, the document with the number is compared to one another, and if the inequality of the numbers is only considered, there are six cases I-VI according to the following table, which are shown in Column 1 is the ordinal number of the case, in column 2 the inequalities, in column 3 the document to be moved,

   in column 4 the choice of the latter and in column 5 the place where the latter is deposited is or are. 7 after <I> A </I> and the one with the number 5 after <I> B </I> and from there past the reading devices to the positions <I> A ' </I> or <I> B '. </I> The read registrations of the numbers are compared with each other in the initial comparison S and the document with the smaller number 5 goes over the switch H into the; Position D, while the document with the number 7 remains in position A '.

   For the second comparison process, the document from batch B with the number 6 for comparison with number 7 in A 'and with number 5 in <I> -D </I> about <I> B </I> after <I> B ' </I> and moved from there via H i to D (case I). For the third comparison process, the document with number 4 appears over B in B '.

   Since the number 4 is smaller than that of the last document stored in D, not it, but the one in position A 'with the higher number 7 can follow the last moved document and go to D (case III). The document with number 4 is now in position B 'and from the sequence A document number 3 comes to the comparison process. This time switch H is switched and document number 3 is moved to position C (case VI). The next comparison process compares document number 4 with document number 2, which was delivered.

   Document number 4 goes as a higher number to position C (case IV). The following document number 1 is then compared with numbers 2 and 4 (case V), with 1 going to position D. This is followed by the final comparisons E, namely, since 2> 1 (E1), 2 goes to D. From the further final comparison 8> 2 (El), 8 also goes to D. This results from this first sorting stage in C or The accumulated documents have the sequence 3, 4, and 5, 6, 7, 1, 2, B. In the same way, a second sorting level in C that follows the same principles results in the sequence 3, 4, 5, 6, 7 and in D 1, 2, B.

   After a third sorting stage, the documents in D are in the order 1, 2, 3 <B> ... Piled up to 8. For the last two sorting stages, it is assumed that sorting with a two-way end comparison is used, which is described later.



  It should be anticipated that sorting without two-way end comparison and sorting with two-way end comparison differ in that the former is stopped when an incoming sequence (batch) belonging to A or B no longer has any documents, while at the sorting with final comparison, the sorting processes as final sorting processes El or E2 (A or B <C or D) until there are no more documents in any of the input memories (successions).



  Assuming that the documents are checks held by individual check carriers, the check forms that are sorted can be of various sizes. In addition to the check, the carrier holds a piece of magnetic strip on which the information relating to the check has been previously recorded. This information can consist of an account number of the check together with the amount of the same. The amount is thus the side information, as mentioned earlier. The two numbers can be drawn one after the other on a piece of magnetic strip.

   It is assumed that the sorting is carried out according to the account numbers and also according to the amounts.



  At the beginning, the two entrances to the sorting machine (not shown) are filled with the documents stacked one on top of the other. The first document in the batch is in positions <I> A </I> or <I> B </I> (Fig. 1). These first two documents are then ready to go through the first sorting stage of the mechanism which provides two new series of documents. It is not essential that the same number of documents be present in both input memories. For the first level of sorting, however, it appears to be desirable that the documents are more or less evenly distributed over the two inputs.

   This gives the best prospect that ordered sequences of documents are sorted in a few sorting levels.



  There can be several sorting stage devices in the machine which are provided with completely similar electrical control equipment. The number of step devices of the sorting machine is determined by the time available for sorting the documents. In fact, the machine could also have a single sorting stage device which is used repeatedly for the different sorting stages until the final sorting stage is carried out, which is characterized by the fact that all documents from the gate position H (Fig. 1) always to the same starting position such as B.

   D (Fig. 1a), ge leads. At this point the sorting process is complete and all documents are classified in the desired order.



  When the document moves from position A to position <I> A ' </I> or from the position <I> B </I> to the position <I> B ' </I>, the piece of magnetic strip on which the account number of the check is recorded together with the amount is read by a magnetic reading device which consists of two heads. The first magnetic reading head reads a first magnetic track on which synchronization information is stored.

   The second magnetic reading head, which is placed next to the first, reads the second magnetic track, which runs parallel to the first and on which the information relating to the account number and amount of the check in the form of changes in the magnetization of the strip along this information track is recorded is. In this solution, a change in the direction of the magnetization on the track can represent one of two binary digits 0, 1, while the absence of such a change represents the other binary possibility. In the present case, however, the number 0 is shown with no pulse and the number 1 with a pulse. This shows the need to use a synchronization track.

   With their help, any changes on the magnetic stripe in each pulse element (bit) of the second information track are determined. The outputs of the two magnetic reading heads are connected to appropriate amplification and shape correction devices for the pulses.



  Fig. 2 shows four terminals, PA1, PB1, PA2 and PB2, to which the pulses from the reading heads between positions <I> A </I> and <I> A ' </I> on the one hand and the positions <I> B </I> and <I> B ' </I> on the other hand. Timing pulses from the reading head are regularly sent to terminal PA1. Corresponding timing pulses appear at the terminal PB1 when a document that goes from position B to position B 'is read. Any information pulses from the information track of a document that goes from position A to position A 'are read at terminal PA2. Correspondingly, any information pulses appear at terminal PB2 if a document is moved from the position <I> B </I> to the position <I> B ' </I> goes, is read.



  For the information pulses, that is to say pulses PA2 and PB2, it is assumed, as already noted, that a pulse appears to indicate the binary number 1, while the absence of a pulse indicates the binary number 0.



  4 shows the pulses which can appear at a pair of terminals PA1 and PAZ or PB1 and PB2. As shown, the timing pulses PA1, PB1 repeat regularly every 200 microseconds, while any information pulses PA2, PB_, which indicate the binary number 1, are in phase opposition to the timing pulses, i.e. i.e. stand in the middle between these.

   The partial information pattern shown in FIG. 4 therefore corresponds to 1011 ... 01 ...



  While a document is moving from position A to position A ', no document is moving from position at the same time <I> B </I> to the position <I> B '. </I> The two pairs of reading heads are therefore never active at the same time. In this way, it is possible to use the gain and shape correction network for both reading positions A, B. FIG. 2 shows that the terminals PA1 and PB1 of the timing pulses in are connected to inputs in the positions which lead to the same mixing gate G1 after they have passed the individual coincidence gates G2 and G3.



  The mixing gate G1 can contain the necessary amplifiers and shape correction means, which are used for the timing pulses. The pulses that appear at these terminals can also have been previously strengthened so that the gates G2 and G .. work with an appropriate level.



  The gate G or G3 is also controlled by an output PA or PB of a comparator CP. The comparator CP is only shown as a rectangle (FIG. 2). Details of this circuit appear in Figures 5 and 6. The four outputs of the comparator CP are represented by terminals PA, PB, PC and PD. The clamps PA and PB are used to generate signals which determine which document is to be advanced towards one of the starting positions C or D (FIG. 1). Either an actuation signal appears at terminal PA, which indicates that a new document should be advanced from input position A, or the signal appears at PB to indicate that the new document is advanced from input B (FIG. 1) should.

   Since terminal P ″ and G2 are connected while terminal PF is connected to G3, either G2 or G3 is able to pass timing signals from terminals PA1 or PB1. These timing signals, which appear at the output of G1 when a document is between the positions A or <I> A ' </I> or between the positions <I> B </I> and <I> B ' </I> is read, are given to the input of the device MS, which converts the timing pulses received from G1 into MS pulses according to FIG. 4; these are applied to the mixing gate G4.

   These pulses have an approximate duration of 30 microseconds and the same time interval as the timing pulses, i.e. 200 microseconds.



  The output pulses of gate G4 serve as pre-switching pulses for the registers SRA and SRB. Each of these shift registers is represented by n + 2 squares (0, 1 <B> ... </B> n + 1). Each of these squares represents a stage of the shift register and can assume two possible electrical states. Accordingly, the shift register can be used to store the dual number n + 1. The additional stage, which is marked 0 and which is separated from the next stage by gates G5 and D, serves as an input stage to allow the ballast pulses to to lag behind any information impulses.

   This was in order to be very useful when possible unwanted phase shifts between the Zeitgabeimpul sen and any information pulses, due to inaccuracies in the reading devices occur. As shown, the ballast pulses are given from output G4 to all stages of the register SRA and SRB. Each ballast pulse causes the digit image registered in SRA and SRB to be advanced one step. After the initial pulse has disappeared, after about 30 microseconds, those tubes which have been ionized beforehand deliver a momentary pulse in their anodes which is sufficient to cause the ionization of the next tube, which forms the next stage.

   Appropriate coupling between the anode circuit of one tube and the control circuit of the next tube is provided.



  The timing pulses appear either at terminal P., 1 or PB1 and any information pulses that correspond to these timing pulses appear either at terminal PA2 or at terminal PB2, depending on a document from the position <I> A </I> after <I> A ' </I> or from the position <I> B </I> after <I> B ' </I> runs. These information pulses are sent through the coincidence gates G9 and G10 and the mixing gate G11 to the inputs of gates G. <B> 7 </B> and G8 given.

   The gate arrangement with Gg, Glo and G "is exactly the same as that with gates G." G3 and G1. As indicated above, the active state at terminal PA or at terminal PB unlocks the A or B path by unlocking gates G9 or G1 ..



  The gates G7 and G8 are essentially an entrance gates for the information according to the registers SRA and SRB. They are controlled by terminals PA and P $ and by terminal P,) 2, on which a pulse condition appears during part of the time which a document needs to move from the position <I> A </I> to the intermediate position <I> A 'too </I> go. A pulse of appropriate duration and location at the terminal Pol is delivered by a photocell array comprising at least two cells.

   These two photocells are not shown. However, they can be assumed to be in series in the current path between A and A '. If the passage of the document, while it is moving to position A ', blocks the first photocell, this instant forms the leading edge of the pulse to be generated at terminal P02. At this moment, the piece of magnetic strip that contains the time information must already be under the corresponding reading heads, while the area of the printed strip with the account number of the check and the amount number is not that far.

    If the leading edge of the document, which is moving towards position A ', now blocks the second photocell, this fact causes the end of the actuation pulse at the terminal Pol. This second photocell is attached in such a way that the actuation pulse on this terminal stops when the piece of magnetic strip is still under the corresponding reading heads, but the information on it has already passed the heads one after the other. The purpose of this authorization pulse at terminal PO2 is therefore essentially to allow the information to be introduced on the magnetic strip only when it is actually located there.

   This is done to avoid erroneous signals that could be picked up by the reading heads before or after the actual information is read and goes to the SRA or SRB. A corresponding authorization pulse also appears at terminal PO2 when a document is moved from the position <I> B </I> to the position <I> B ' </I> goes. This impulse is generated in exactly the same way by a photocell array which this time is attached to the path of the documents which are between the positions <I> B </I> and <I> B ' </I> move.



  From the foregoing it can be seen that when a document is being read, the timing pulses at the output of G1 always generate feed pulses at the output G4. These are used to put the information image in front of the SRA and SRB, regardless of whether the document that is being read is an A or a B document. At the same time, the information pulses either go through G7 or G8, depending on whether an A or a B document is being read.



  If it is assumed that a timing pulse, i.e. a ballast pulse, always follows a possible information pulse, and that the images of n dual digits are already registered in levels 1 to n of SRA and SRB, the first ballast pulse pushes these two images ( also called pattern) by one level, so that they occupy levels from 2 to n + 1 in SRA and SRB. Immediately before this first ballast pulse, however, the presence or absence of an information pulse on the A-document caused the level O of SRA to only be put into the state which corresponds to the first binary digit.

   If a pulse appears in the output of G7, it is assumed that the SRA's O stage is holding a 1, while it is recording an O if no such pulse occurs.



  Further pre-switching pulses push the images in the registers SRA and SRB on. When the image is advanced in SRA, a new information image is gradually written down and represents the new information read from the document which is different from <I> A </I> after <I> A ' </I> moves. While the previous information pattern that was registered in SRA is gradually released from this shift register and is lost because the dual digits exit one after the other from the last level n + 1, this is not the case for the provisional information pattern that was registered in SRB the case. Since it has been assumed that the terminal PA is excited, the coincidence gate G12, which couples the stage 1 with the stage n, is unlocked.

   This gate G12 is also controlled by the device BS1 which, as will be described later, goes into state 1 when it is started. Therefore, when the terminal PA carries an active signal, the gate G12 is unlocked, and since the original information pattern advances through SRB, it is progressively registered again through gates G12 and G6.



  Between levels n and 1 of SRA there is a similar coupling with the coincidence gate G13 and the mixing gate G .. The coincidence gate G13 is controlled by the active state at the terminal PB ge. It is assumed that it is ineffective in the example described.



  When the first digit of the pattern previously registered in SRA enters the stages; - 1, the first digit occupies the information read from the A document that differs from the position <I> A </I> after <I> A ' </I> moved, the level 1 of SRA. At the same time, the first digit of the image that was previously registered in SRB occupies levels + 1 of SRB and level 1 of SRB, since this original information pattern is able to circulate through Gl2. Step 1 of SRA and SRB are connected to terminals PAB and PBA, respectively. The stages n + 1 of SRA and SRB are also connected to the terminals PCA and PCss of the comparator CP.



  The comparator CP, which is shown in FIGS. 5 and 6, can compare two states which appear successively at the terminals PAB and PssA with one another. He can also compare the states at terminals PAB and PCA. He can also compare the states at the terminals PPA and PCB.



  In this way, while a number is being introduced into SRA to replace the outgoing number C previously stored in SRA, and while a number already stored in SRB is scrolling, the comparison between A-B, A-C and B-B is carried out simultaneously. On the other hand, while a new number B is being introduced into SRB to replace an outgoing number C previously stored in SRB, and while a previously stored number A is circulating in SRA, comparisons between B -A, BC and AA are made simultaneously executed.



  One notices that one of these three comparison processes is always meaningless (B-B, A-A), since it only compares the previously stored number with itself. This particular comparison process can therefore be used to check whether the processes are running correctly. The other two comparison processes apparently do not allow the comparator CP to determine the sequence of the three numbers, since in one case the comparison B-C and in the other case the comparison A-C are not carried out.

   However, as will be explained later in connection with FIG. 5, the comparator CP is designed in such a way that two useful comparison processes still suffice for the order (order) of three numbers <I> A, B </I> and C, and accordingly to excite the terminal PA or PB so that they cause one of the two documents A or B, in accordance with the result of the comparison processes, to move to the switch position H (Fig. 1 ) go. Likewise, the comparator CP generates an actuation signal, either at the terminal PC or at the terminal PD, after which it gives a display to the control circuit of FIG. 3, according to which from output C or D (Fig. 1) the outgoing document are performed should.

   Therefore, there are four possible results in the comparison processes carried out by CP.



  2 also shows that the timing pulses after MS1 go to terminal P1 of the comparator CP. These pulses are used in a manner which will be described later. Furthermore, the terminal P, - "" at which the authorization pulses from the photocell appear, is also connected to the terminal P. of the comparator CP. A capacitor differentiates the authorization pulse, the front edge of which is used for resetting operations, while the rear edge is used to generate actuation signals at one of the two terminals PA or PB and at one of the terminals PC or PD.



  The pulses at terminal P, -, 1 have a duration of 30 microseconds and are repeated every 200 microseconds. They are generated locally and are permanently available at the entrance of the coincidence gate G14. When sorting starts, BS1 is tilted into its O position for a short time. This time is sufficient for a number of locally generated ballast pulses at terminal PO1 to flow through gates G14 and G4 in order to advance any pattern stored in SRA or SRB. The purpose of this operation is to clear the SRA and SRB registers so that when new sorts are started, all of the SRA and SRB levels are 0.

   It is necessary that no numbers are contained in SRA and SRB at the beginning of the sorting process, otherwise if the first number A, which should be stored in SRA, for example, could have such a relation to any numbers stored in SRA or SRB, that the shift of document A could result forwards. This would mean that the next A-document would be registered in SRA, so that there would be no opportunity for the first B-document to be guided through the switch position H (FIG. 1) immediately after the first A-document was connected upstream.



  Finally, the comparator CP shows three additional input terminals P3, PAC and PBC, to which signals can possibly be applied from the sequence control circuit of FIG. 3, the purpose of which will be described later.



  With reference to FIG. 3, the description of the different work sequences which arise at the beginning of the sorting is now made. If it is assumed that both input storage positions have been filled by a number of documents to be subjected to sorting, and that the input positions <I> A </I> and <I> B </I> are occupied by the first documents, the start key can be pressed, whereby the closing of the contact k (Fig. 3) is accomplished. Via the isolating contact t1 of the stop relay Tr, a circuit is established between earth and the battery at terminal PF. This energizes the start relay Sr.

   The contact s1 holds the relay Sr independent of the contact ks via the normally closed contacts aa1 and bd1 in series. The changeover contact s2 opens the connection between the terminal PF and the O input of BS1 (Fig. 2). As a result, BS1 (FIG. 2) is put into its O state if it was not already in this state.



  The response of relay Sr excites via the normally open contact <I> s., </I> the relay <I> Aar </I> or the relay <I> bar </I> via the normally open contact s4. Which of these two relays works is dependent on the original status of the comparator CP (Fig. 2). It does not matter which of the terminals PA or PB and PC or PD is energized at the start of the process. For example, it may be assumed that terminal PA is energized while terminal PB is not. This means that the relay <I> Ar </I> is energized while relay Br is not energized. That is why the relay works <I> Aar </I> in a circuit which has resistance Ra, contact s3, the winding <I> Aar, </I> includes contact ac1, a1 and e1.



  The response of relays <I> Aar </I> controls a mechanism which is able to bring a document which is in the A 'position to the H switch position. If no such document is in this intermediate position, this first process has no effect.



  When the relay <I> Aar </I> responds, it closes a holding circuit via its normally open contact. It is assumed that the resistance of Ra is low compared to that of relay Abr, so this relay cannot work at this moment.

   The response of relays <I> Aar </I> also closes contacts aa4 and aa3. Depending on which of the two terminals PC or PD is excited by the comparator CP (Fig. 2), relay Cr or works <I> Dr. </I> It is assumed that, for example, via aa,

      the relay Cr can work. Then the relay Cr holds through the contact c1 in series with the contacts hbi and sc4 to earth.



  When the normally open contact s5 is closed, the relay Sar- works and stays in series with the isolating contact sci via its contact sai. After the relay <I> Aar </I> has been actuated, the contact opens and causes relay Sr. to drop out.



  When the contact s3 opens, the resistance closes R. the winding of the relay Abr no longer shorts, and the latter relay can finite the relay in series <I> Aar </I> work through these series contacts aal, acl, a1 and e1. The contact is closed and the relay <I> Aar </I> is short-circuited and drops out and opens its contact aa2. The relay Abr remains off via its normally open contact.

   The dropping of contact s2 into the position shown interrupts the potential from terminal PE for the O input of BS1. As previously explained in connection with the interruption of BS1, O, these processes cause BS1 to tilt to its position 1. From this moment on, the information is allowed to circulate again either for SRA or SRB, specifically for the latter in the present case , since the terminal P, is live.



  Relay Sr is a slowly decaying relay, the delay of which is long enough to ensure the erasure of the pattern originally stored in SRA and SRB.



  After the relay <I> Aar </I> has been released while the relay Abr was held, a working circuit for the relay Acr is closed via the isolating contact aas, working contact from "the winding Acr and the isolating contact ei.



  The relay Acr operates and causes the first document in the A-entry position to be moved towards the intermediate position A '. On its way to position A ', the first A-document is read and the read number of the document is compared with the number of the documents which are stored in the SRA and SRB (FIG. 2). Since the records in SRA and SRB have now been deleted and the numbers 0 have been recorded, the number of the first document A is greater than the number of the non-existent documents. This means that the first A-document should not be the one that is brought into the switch layer H, but that it should be the missing document, which corresponds to the record O in SRB, that should be conveyed forward.



  In the meantime and as soon as the relay Acr had worked, a circuit for the actuation of the relay Sbr was established via the contacts sag and ac2. After work, the relay Sbr is maintained via the normally open contact sb1 and via the winding of the relay Scr, regardless of the contact ac2. As long as this contact remains closed, however, the relay Scr is short-circuited and cannot work. The actuation of the relay Acr also opens the contact ac1, whereby the holding circuit for the relay Abr is opened and this relay drops out. In turn, the dropping out of relay Abr opens contact ab2 and relay Acr drops out, whereby relay Scr can work in series with relay Sbr.



  In order to prevent that after the response of Scr and the dropout of relay Acr, the relay <I> Aar </I> can work when the relay <I> Ar </I> has not yet been de-energized, a holding circuit is provided for the relay Acr. This includes the working contacts ac3, a2 and sb2 in series. Therefore, as long as the relay Ar is operated, the relay Acr cannot drop out. If the latter relay returns to the rest position, the comparison circuit has worked correctly and the relay <I> Aar </I> cannot respond after actuating relay Scr.



  In the meantime, until the first document finds the intermediate position A ', relay is working again <I> Aar </I> prevents, because the possible working circuit for this relay at contact ac1 and also at contact a1 is open because, caused by the aforementioned comparison process, the actuation potential at terminal P, (Fig. 2) has disappeared and has been replaced by an actuation potential at terminal PB, which caused relay Br to respond.



  If the relay Scr works, the contact can <I> <U> se., </U> </I> the relay <I> Aar </I> do not operate the operating circuit for the relay while the contact is being made <I> bar </I> closes. This contains the resistor Rb, the normally open contact sc3, the winding Bar, the contact bc1, the normally open contact bi and the isolating contact e1. As before for the relay <I> Aar </I> was mentioned, relay Bar is now held in series with the winding of relay Bbr via contact ba2, which cannot work as long as it is short-circuited by resistor Rb.



  When working, the relay Scr opens the contact sc1 to open the holding circuit for the relay Sar, which drops out and in turn releases the relays Sbr and Scr. Therefore, the four start relays Sr, Sar, Sbr and Scr are now triggered because they have done their job.



  The operation of the relay <I> bar </I> causes the corresponding mechanism to place a document in the intermediate layer <I> B ' </I> to the point position <I> H </I> to advance. However, this process still has no effect since the B document is still missing here. After relay Scr has dropped out, relay Bbr can respond, as it is no longer short-circuited by the resistance Rb. A holding circuit is closed for this relay. This runs via the normally open contact bb1 and closes the relay <I> bar </I> in short, that falls off. At this point, a circuit is established through ba5 in series with bb2 to operate relay Bcr.

   The response of relay Bcr then causes the first document in the B input position to be shifted to the B 'intermediate position, whereby it goes through the corresponding reading position.



  When relay Scr responded, the opening of its contact sc4 interrupted the holding circuit for relay Cr, which dropped out. This means that contacts c2 and c. are now open.

   Although now the first A and the first B documents in their respective positions <I> (A ', B') </I> are and accordingly the occupied intermediate position contacts ka2 and kb2 <I> ge </I> are closed, neither the relay <I> Aar, </I> nor the relay <I> bar </I> be short-circuited by its own isolating contacts aas or bca6, since the relays Cr and Dr- have dropped out.



  Depending on which number of the two documents <I> A </I> or <I> B </I> is smaller, the comparison circuit CP causes the document with the smaller number to be advanced to the switch position H. This document is therefore the first to go through this point position.



  As indicated above, contacts ka2 and kb2 are interlayer contacts. They are closed when an object to be sorted is in the appropriate intermediate layer <I> A ' </I> or <I> B ' </I> is located.



  If it is assumed that the A-document has the smaller number, the terminal PA was energized when the first B-document passed through the corresponding reading position and accordingly becomes relay <I> Ar </I> actuates and enables relays to be energized <I> Aar. </I> This time the actuation circuit contains contact ka2 instead of the contacts of the relay Sr or Scr. In exactly the same way as previously described, the relay initiates <I> Aar </I> the first document from <I> A ', </I> in the switch position <I> H </I> to go. This time, however, the actuation of the relay Abr is due to the fact that the first A-document has left the intermediate position A ', opening the contact ka2. After relay Aar has responded, relay Cr works again via normally open contact aa3 because terminal PC is still activated.

   After relays drop out <I> Aar, </I> which was caused by the response of the Abr relay, the Cr relay is held via the contacts cl, hb1 and sc4. The relay Acr operates again to cause the second A document to be moved out of the input position A and take the place of the first document A and A '. For its part, relay Abr now also drops out and causes relay Acr to de-energize. The activation time of relay Acr, like that of relay Aar, is sufficient for the document to be started either in the intermediate position or in the switch position.



  If z. B. when passing the second A document through its reading position it is determined that its number is greater than that of the first B document, but the latter is greater than the number of the first A document that went after the H position , the comparison device CP indicates that the first B-document is to be moved to the switch position H.



  Therefore the terminal Pb could be energized, thereby actuating the relay Br instead of the relay <I> Ar </I> would be brought about. However, when the contact B1 is closed and the relay Cr is operated, the relay Bar is short-circuited by the series contacts kb2, sc3, bah and c3 and cannot work. This ensures that the document is prevented from being used by one of the Intermediate positions to be promoted to the switch position if the latter is still occupied by a previous document. The contacts ka2, se 2 aas and c2 / d2 form a similar short circuit for the relay Aar.



  When the first A-document has completely reached the switch position H (FIG. 1), the two switch contacts ka3 and kb3 are closed. The contact ka3 is closed when a document A comes into the switch position and the contact kb3 is closed when a document has arrived from the intermediate position B '. However, precautions have been taken here that the contact kb3 is also closed after contact ka3 has been closed in the case of the displacement A'-H, and vice versa for a B document that is sent from <I> B ' </I> after <I> H </I> is running.



  After these two contacts ka3, kb3 have been closed, the relay Har works and, via its contact ha1, remains in series with the winding of relay Hdr and contact c4. The response of relay Har actuates the relay Hcr via the contact, hb2 and contact c5. The relay Hcr shifts the points containing the A document to the output position to C. The relay Hdr would of course have set the occupied points to the output position D if the relay <I> Dr </I> would have addressed. After the position of the occupied turnout has been changed, there is a working position contact <I> of </I> the turnout is an additional holding circuit for the relay <i> Har. </I>



  It is assumed that - when the occupied switch has been moved into its working position, the document which is present on the switch automatically goes into the corresponding output position. If the document leaves the switch position, it is further assumed that means, not shown, cause the switches to automatically return to their normal position. Then it is ready to accept another document from an intermediate position. The contacts kb, and ka, are opened one after the other when the first A-document leaves the gate in direction C. At this point, however, the relay Hbr is still through contact <I> of </I> shorted.

   When the switch swings back to its normal position, contact is made <I> of </I> opened and accordingly the relay Hbr works in series with the relay <i> Har. </I> The relay Hbr opens the holding circuit for the relay Cr at contact hbl, which drops out and in turn the relay <i> Har </I> and Hbr releases by opening its contact c4.



  Via contact hb, the temporary operation of relay Hbr immediately causes relay Hcr to drop out.



  After the relay Cr has dropped out, the contacts c2 and c3 are open and either the relay <I> Aar </I> or the relay <I> bar </I> via the contacts ka2 or kb, depending on the result of the comparison process. If <I> Aar </I> works when <I> Ar </I> is energized, or whether the relay <I> bar </I> responds when the relay Br \ is energized, results in operations similar to those just described.

   After addressing <I> Aar </I> or <I> bar </I> Either the relay Cr or the relay works <I> Dr. </I> Since the first A document reached the C output position, it is clear that the relay <I> Dr </I> can only work if the terminal PD receives a pulse after the number of the first B document and the second A document is smaller than that of the first A document, which is equivalent to the state that a change in From put on the output pile C, D indicates.



  The sorting continues in the manner explained until the last document from one of the two input memories <I> A, B </I> to the corresponding intermediate position <I> A ', B' </I> has arrived. According to the control by the comparison circuit CP, this document remains in the intermediate position (z. B. B '), while A-documents can still be sent through the switch without it being necessary that the last B-document in a Output sequence is brought. After this last B-document has been placed in the switch position, it is not replaced by a further B-document. Therefore, no further information is sent to the comparison circuit CP, which remains in the state that caused the last B-document to be brought into the switch position.

   Therefore the sorting process is stopped at this moment. A document A can be in the corresponding intermediate position A 'and further documents can perhaps remain in the A input memory.



  This kind of sorting is called sorting without two final comparisons (E). The machine stops when one of its entry positions A or B has been emptied. In order to bring about the continuation of the processes, it is necessary to replenish this entry position. If the sorting level under consideration is not the first incoming sorting level in the case of several successive sorting levels, it is possible to wait until the preceding sorting level delivers further documents to their inbound storage.

   By temporarily closing the contact ks again, the machine can now be started and the sorting process can continue. This process can of course also be done automatically by a contact arrangement. This contact arrangement would determine whether documents are present in both input memories and, if necessary, trigger analog functions after the contact is closed.



  In addition to sorting without a two-way end comparison, sorting with a two-way end comparison can also be used. This consists in performing the sorting operations at any stage as long as there are documents in one of the two input stores, regardless of the fact that the other input store has been emptied. In this case, the documents that remain in an input memory are sorted further in their present sequence, possibly distributed between C and D. However, depending on this input sequence, the documents are given to one or the other of two output memories (C, D) in the sense of the sorting processes E1, E.2 set out above.

   Therefore, with this type of sorting, one of its two input memories can be used in one sorting stage <I> (A, B) </I> temporarily emptied, but later filled again by documents that originate from previous sorting levels.



  If the sorting with final comparison is desired, the contact kv (Fig. 3) is permanently closed by means of a corresponding key. If it is assumed that after a certain time the B-memory is emptied and not immediately filled again, the contact kb1 is broken, which has normally been actuated by the first document that goes out of the B-memory, if the last B-document moves into the intermediate position. After the relay <I> bar </I> is actuated when the last B-document in the B'-intermediate position has been conveyed to the switch position H, a working circuit for the relay Bdr closes via the isolating contacts t "" kb1, working contact ba7, the winding of relays Bdr and normally open contact kv and the isolating contact ei.

   The relay Bdr responds and stays in series with the isolating contact f l via the normally open contact bd1. After the relay Bbr has responded in the normal way, the relay drops <I> bar </I> off and relay Bcr responds. The latter has no effect as there are no documents in the B entry position. The energization of relay Bcr causes relay Bbr to drop out, which in turn releases relay Bcr.



  After the relay Bdr is energized, the order switch contact bd2 is switched and the connection between the terminals PE (Fig. 3) and PBC (Fig. 2) is interrupted. As will be shown later, this interruption, as long as it lasts, causes the comparison circuit CP, which until now has remained in the previously assumed state, which caused the further conveyance of the last B document to the switch position, to indicate that CP B> C. Furthermore, after switching the contact bd2, which establishes a connection between the terminals PE (Fig. 3) and PC (Fig. 2), a pulse is applied to the comparative circuit CP, for the purpose of reversing the output for that A document that is to go to the point position in a manner to be described later.



  Furthermore, the relay Bdr closes its working contact bd3, which overpresses the contact a1, so that regardless of the state of the relay <I> Ar </I> or Br always a working circuit for the relay <I> Aar </I> is established after the contact ka., Which is the busy contact for the intermediate position <I> A ' </I> represents. On the other hand, the relay can <I> bar </I> from the moment that the last B-document has left the intermediate position B ', cannot be actuated again because the occupied contact k6. Is not closed again.



  The reasons for the above-mentioned processes, which were caused by the response of relay Bdr, can be explained as follows: When the last B-document reached switch position H, this meant that the comparison device A> B> C indicated or its two cyclic derivatives, that is <I> B> C> A </I> <I> C> A> B </I> B means the number of the last B-document, A the number of the first remaining A-document and C the number of the document which immediately preceded the B-document by the switch position H.

   Since no further B documents have been moved through the corresponding reading position, the comparison circuit is normally not influenced and remains in the state of one of the three above-mentioned inequalities. This shows that the comparator is still showing that a B-document should be sent to the point position. Since this display does not make sense, the closing of the working contact bd3 creates a remedy, which allows the first remaining A-document to be sent to the switch position after the latter has been released by the last B-document.

   Depending on the relationship between <I> A </I> and <I> B, </I> that means between the first remaining A-document and the last B-document, the A-document either follows the same direction as the B-document or not. It is clear that if A> B, then A goes in the same direction as <I> B. </I> If however <I> B> A </I> is, follows <I> A </I> the opposite direction that B has taken to start a new output sequence with the first remaining A document. However, the comparison circuit CP would only display the reversal of the output in the case of a state C> A> B, which in the particular case of the first remaining document would be wrong for this type of sorting.

   Likewise, if the state that caused the comparison circuit to convey the last document B, <I> B> C> A </I> would have been, no change in the output for the last B document would have been displayed and accordingly no change in the output for the first remaining A document.



  A very simple solution for conveying the first remaining A-document to the correct output position can be found if the comparison device CP is designed in such a way that when it has an individual state
EMI0011.0008
  
     <I> C <SEP>> <SEP> A <SEP>> <SEP> B </I>
 <tb> or <SEP> <I> C <SEP>> <SEP> B <SEP>> <SEP> A </I> perceives, which means a change in the output direction, it starts a new sequence with the lowest A or B document. After this display has been received and used, the comparator CP is automatically reset to the relevant status.

    
EMI0011.0011
  
     <I> A <SEP>> <SEP> B <SEP>> <SEP> C </I>
 <tb> or <SEP> <I> B <SEP>> <SEP> A <SEP>> <SEP> C. </I> This means that the relationship between A and B is maintained as received, but that on the one hand the relationship between A and C and on the other hand between B and C are both artificially reversed.



  Accordingly, of the three possible states that have been mentioned above as those that are the only ones that cause the last B-document to be advanced, only two remain, that is
EMI0011.0014
  
     <I> A <SEP>> <SEP> B <SEP>> <SEP> C </I>
 <tb> or <SEP> <I> B <SEP>> <SEP> C <SEP>> <SEP> A, </I> because the third state has been automatically and artificially converted into the first of the two above.



  If, as already mentioned, the response of the relay Bdr via contact bd2 changes the state B, C of the comparison device to the state <I> C, B </I> changed the two possible conditions too
EMI0011.0017
  
     <I> A <SEP>> <SEP> C <SEP>> <SEP> B </I>
 <tb> and <SEP> C <SEP>> <SEP> B <SEP>> <SEP> A. It is clear that these latter two states indicate that A should be advanced in the same direction as <I> B, </I> or that A is in the <I> B </I> is sent in the opposite direction (it should be remembered that C is always used to indicate the preceding document that was transported to the points and which in this case was the last B document).



  The above-mentioned changes in the state of the comparison circuit CP, which follows after the actuation of the relay Bdr, would however remain without effect insofar as the actuation of the output terminals PA, PB, PC -i PD of the comparator CP are affected because it It should be remembered that the comparison processes take effect after the impulses at the Pol terminal have stopped. Therefore, regardless of the forced change in the state of the comparison circuit, caused by the opening of the contact bd2, the terminal PB remains in the energized state and consequently the relay Br remains addressed.

   In view of the closing of the contact bd3, which anyway causes the promotion of the first remaining A document, this would have no consequence. But if the terminal PC carried an impulse when the last B-document went over the switches, and if <I> B> A, </I> the actuation of this last clamp should be replaced by that of clamp PD, in order to allow the first remaining A-document to be moved into the starting position, which is opposite to that

       in which the last B-document moved. The missing trailing edge of the authorization pulse, which normally appears at terminal PC, is replaced by a pulse generated by the pulse of the connection between terminals PF and P2, which pulse takes advantage of the changed state of the comparison current circuit CP. Therefore the terminal PC becomes dependent on <I> A> B </I> excited or not. The de-excitation of this terminal results in the excitation of terminal PG.



  In fact, the only two possible states that can be obtained by actuating the relay Bdr cause the terminal PP to de-energize, thereby releasing the relay Br while the relay is in operation <I> Ar </I> is now working as a result of the excitation of terminal PA.



  Therefore, the first remaining A-document is sent to one of the two starting positions, depending on its numerical value, and the further remaining A-documents are given successively to the switch position H in order to be subsequently guided to one of the two output positions. A change in the starting position is obtained every time the sequence of the remaining A documents ends.

   Therefore, the remaining A documents are distributed to the two output or starting positions, according to their input sequence, and the principle of distributing the documents to the two output positions according to the available sequences is maintained.



  Although the relay was shown <I> Ar </I> works in any case for the first remaining A-document, the closing of the contact bd3 plays a role regardless of this during the processing of further A-documents. Since, as mentioned, the comparator was forced into a state by opening the connection between terminals PF and PrG, which corresponds to C> B, the three possible states that influence the comparator are as follows:

    
EMI0012.0011
  
     <I> A <SEP>> <SEP> C <SEP>> <SEP> B </I>
 <tb> <I> C <SEP>> <SEP> A <SEP>> <SEP> B </I>
 <tb> or <SEP> <I> C <SEP>> <SEP> B <SEP>> <SEP> A. </I> The first and last status above cause the A-document to be transported, the latter also to the other output stack. The second state, however, corresponds to a B document that goes to the other output stack than the previous one. Therefore, in the last case mentioned, the working contact bd3 should make it possible for the A-document to be conveyed in the intermediate position A ', specifically in a different direction than the direction followed by the preceding document A.



  While the last of the remaining A documents is being conveyed into the intermediate position A ', the contact ka1 is closed, namely from the A input position which is emptied. After speaking to relay Aar, relay Adr works in the same way as Bdr worked before. After the relays Bdr and Adr are both energized, the relay works <I> Ms. </I> via a circuit which contains the contacts ad, and bd4 in series. As a result, the holding circuit for these two relays at the isolating contact f 1 is interrupted. Relays Adr and Bdr drop out and trigger relay Fr.

   The latter should be delayed in order to ensure that both relays Adr and Bdr are released before the relay Fr closes its contact f 1 again.



  After the switch position H has been released by the last A document, the circuit is also completely free. During a sort, it may seem desirable to stop the sorting process. It may seem desirable to stop the processes and carry out a completely new sorting, or to interrupt the processes only temporarily and then start them again at a later moment.



  If the sorting should be stopped, the contact will <I> kt </I> temporarily thrown by an appropriate push button and results in the response of relay Tr via the isolating contact s. of the start relay, which must be in the rest position at this moment and via the isolating contact ku2. When responding, the relay Tr prepares an actuating circuit for the relay via a normally open contact t2 <i> He </I> before. The latter is triggered by one of the two relays <I> Aar </I> or <I> bar </I> completed in the actuated state to indicate that a document has reached an intermediate layer and should now be brought into the switch position.

   For example, the closing of the normally open contact causes aas when the relay responds <I> Aar </I> the excitation of relays <i> He. </I> This relay is kept in series with the isolating contacts hb1 and sc4 via its normally open contact e2. The actuating circuit of various relays is interrupted at the working contact. In particular, the relay Acr is prevented from working after the A document has actuated the relay <I> Aar </I> has initiated. Therefore, no further A documents are transported to the intermediate position A '.

   Sorting is ended because the comparator CP is now in a state in which the relay <I> Ar </I> is excited and, accordingly, since the relay Br is in the rest position, the B-document in the corresponding intermediate position blocks the further conveyance of documents, this time for the B-entry position. The relay Er drops out after the temporary activation of the relay Hbr, after the points have been moved into their normal position and the last A document has been moved to one of the starting positions. The sorting is thus definitely finished, all relays have returned to the rest position, with the exception of the relay <I> Ar. </I>



  It also has the operation of relays <i> He </I> causes the interruption of the connection between terminal PF and the 0 input of BSl via its isolating contact e3. As a result, BS1 is reset to the 0 position, as already explained, with the result that the local pre-switching pulses at terminal Pol delete the numbers in SRA and SRB.



  If an intermediate stop is desired, the processes are related to those just described, with the exception of the response of relays <i> He </I> is effected by closing the contact ku1 of a key. In such a case, however, the relay Tr is not operated. In its place the relay Ur is energized via the normally closed contacts s6 and kt and the working contact ku2. It is held in series with a3 or b3 via contacts u1, sb3. Therefore, regardless of contact e3, the connection between terminal Pf and the O input of BS1 via contact u.> Is maintained in order to avoid deleting the registers SRA and SRB.

   As the relay <I> Ar </I> and consequently <i> Ur </I> remain in the actuated state during the intermediate stop, if sorting is restarted by closing contact ks, the shifting of contact s2 cannot interrupt the connection between terminal PE and the O input of Bs1. Therefore, in this particular case, the register SRA and the register SRB are not cleared at the beginning of the operations, so that the numbers previously stored in this register are used to decide whether or not the document that remained in the intermediate position B is the new document A, which was sent to the corresponding intermediate position, is to be brought into the switch position and then to one of the output positions.

   After the relay Sbr has been actuated, which means that the relay Sr has dropped out at this time, the holding circuit for the relay Ur at contact sb3 is interrupted and this relay drops out, without the possibility of the connection between terminal PE and the O input of BS1 is interrupted. The relay <i> Ur </I> falls delayed, so that it holds during the fall of Ar when the latter is replaced by the actuation of Br and vice versa.



  The control of the sequence of operations has now been fully described. The comparison device CP will now be explained in detail with reference to FIG.



  The comparator CP of FIG. 5 is equipped with three comparison units CPA, CPB and CPC, each of which is provided with four input terminals, such as. B. P10, P2c, P3c and P40 for CPC, and with two output terminals, such as P5C and P6C for the same comparison unit. The three comparison units are absolutely identical and CPC is shown in detail in FIG.



  As FIG. 6 shows, each comparison unit contains a bistable device, a monostable device, six gates and two inverters. The terminal PIC shown by Fig. 5 is connected to the terminal P1 shown in Fig. 2, and receives timing pulses from the document being read and forms an input to the coincidence gate G14, the the other input is excited when the device with two stable layers BS2 is in state 1. This state is reached after a pulse from terminal P2C. This terminal is in turn connected to terminal P2 (FIGS. 2 and 5).

   A pulse appears at this terminal which corresponds to either the leading or trailing edge of the authorization pulse that appears at the Pol terminal when the document is read. It is assumed that only the leading edge of this authorization pulse is effective to flip BS2 into its state 1. From this moment on, each timing pulse is able to go through gate G14 and tilts the device with a stable position MS2 in its abnormal state, that is to say in its working position, where it remains during the period of 60 microseconds. When MS tilts back into the 0 position, a triggering pulse, called the comparison pulse, is generated at the output.

   This goes in FIG. 6 through a capacitor coupling at the O output of MS2 and lasts until MS flips back into its normal state. Therefore, MS acts as a delay device and the comparison pulses, at its output as timing pulses, are shown in FIG. These pulses go to the inputs of the coincidence gates G15 and G16, the outputs of which form an input of the coincidence gates G17 and G18, the outputs of which are connected to the terminals P5C and P6C. Another input of gate G15 comes from terminal P3C, while another input of G16 is connected to terminal P4C. Furthermore, the terminal P30 is connected to the input of the inverter 11, the output of which forms the second input of the gate G18.

   On the other hand, terminal P4C is connected to the input of inverter 12, the output of which forms a second input for G17. Finally the terminals P50 and P6C act as inputs for the mixing gate G19, the output of which is connected to the O input of BS2.



  As can be seen from FIGS. 5 and 2, the terminal P30 is verbun with the first stage of SRA, through the terminal PAB. On the other hand, the terminal P4C is connected to the first stage of SRB through the terminal PBA. This means that the G17 is forming. Finally the terminals P5C and P6C and P4C appear, correspond to the digits that are being written into level 1 of SRA or SRB at this time.



  In the described registers of n -I- 2 levels, any information pulse precedes the corresponding timing pulse by 100 microseconds, as shown in FIG. Therefore, with the preceding number C, which is stored in SRA, in stages 1 to n, when the reading of a new number A begins, the first possible information pulse is registered in stage O of SRA.

   In other words, if each stage of a register consists of a cold cathode tube, it is ionized in the presence of a first information pulse, which identifies the binary number 1. On the other hand, if there is no information pulse that corresponds to the binary level O, the level O is not ionized by SRA. 100 microseconds later, the first timing pulse advances the pattern stored in SRA and SRB one level.

   This means that the previously registered numbers C and B are now registered in levels 2 to n + 1, while the first digit of the new number A remains in level 1 of SRA and SRB, respectively. Since the first timing pulse, which appears at terminal P1C (Fig. 6), a 60 microsecond delayed comparison pulse it generates, which is applied to gates G15 and G16, this comparison pulse is able to the states at terminals P3C and P4C with each other to compare.



  While the state at terminal P3C now corresponds to the first binary digit of the number A, the electrical state of terminal P4C corresponds to the first binary digit of number B, which was previously identified in SRB and which is allowed to circulate in this register.



  Assuming that a digit 0 in level 1 of SRA or SRB indicates an operating potential on the terminals <b> Pp </B> C or PVC, the corresponding gate C15 or C18 is conductive to allow the comparison pulses to pass, which are derived from the timing pulse. Since the gates G17 and G18 are controlled by the terminals P4C and P3C by the Inver ter 12 and II, a number 0 blocks the corresponding gate G17 or G18, while a number 1 makes the corresponding gate G17 or G18 conductive so that it is the Comparison pulse picks up.

   This means that if the first binary digit of A and B is both 0 or both a 1, the comparison pulse is blocked either through gates G17 and G18 or through gates G15 and G16. If the first binary digit of A is a 0 while the first binary digit of B is a 1, gates G15 and G17 are conductive, while gates G16 and G18 are blocked. The comparison pulse can therefore reach terminal P5C through gates G15 and G17. If, on the other hand, the first binary digit of A is a 1 while the first binary digit of B is a 0, the comparison pulse appears at terminal P6C.



  As soon as a pulse appears at either terminal P5C or P6C while the number A is currently being introduced into SRA, and at the same time the previously registered number B in SRB passes through stages 1 to n of the shift register, the comparison pulse goes through G " This blocks gate G14, which means that the next timing pulse at terminal P1C is unable to generate a corresponding comparison pulse.



  The reason for this blocking effect, as soon as a comparison pulse appears either at the terminal P5C or P6C, is that it has been assumed that the binary digits which have been used to identify the number have been ordered so that the first binary digit of any number has the greatest importance while the last is of least importance, and that in general the meaning of any binary digit is less than that of the preceding digit and greater than that of the next digit. The above does not necessarily mean that the numbers have to be registered as binary numbers.

   They are only registered with the help of binary digits in some appropriate way, but in such a way that when all the numbers are ordered, all the relevant binary numbers correspond to the encrypted representation and appear in the same order. For example, four binary units could be represented. The first four binary digit elements would correspond to the decimal digit of the highest priority, etc. Furthermore, in every combination of four binary digit elements that represent a decimal digit, the first element has the greatest importance, i.e. in terms of numbers the greatest significance, etc.

   For example, the following code could be used to identify decimal digits: 0 0000 5 1000 1 0001 6 1001 2 0010 7 1010 3 0100 8 1100 4 0101 9 1101 From this code it can be seen that the first binary digit element has the constant meaning of 5 etc. Depending on the rank of the decimal number in question, this meaning is multiplied by the corresponding powers of ten.



  It is clear that a code could also be used whose first digit is the least significant. In such a case, the gate G19 would have to be suppressed, and the last comparison pulse would appear either at the terminal P. ,, or P, (., Which would decide which of the two numbers is larger. Since, as shown in Fig. 5 shows that terminals P5C and P6C lead to corresponding inputs of the two devices BS3, this can be toggled each time during the comparison of two numbers.



  However, only the last pulse that appears on one of the two terminals would give the correct result of the comparison. If, therefore, it is assumed that the status of BS3 is not used before all digits of the two numbers have been compared with one another, the scheme shown in FIG. 6 could also be used if the binary digit of the least significance comes first appeared.



  It should be noted that the arrangement of FIG. 6 does not require comparison between pulses of essentially the same length. The state at terminals P3C and P4c remains for approximately 170 microseconds, and the comparison pulse at the inputs of G ″ and G16 is a very short duration trigger pulse.



  The shift registers SRA and SRB of FIG. 2 are provided with an (n + 2) th stage, which appears at the input as a 0 stage. This could be omitted if the timing pulses, instead of running behind the information pulses 100, us, preceded them by the same amount. It is essential that there are at least n + 1 levels in the registers so that one digit of the number coming up, such as B.

   A, can always be compared with a number corresponding to the range of the number circulating in B or with a number C which leaves SRA.



  It is essential that there are at least n + 1 levels in the registers so that a digit of the incoming number, such as e.g. B. A, can always be compared with a number corresponding to the range of the number circulating in B or with a number C, which leaves SRA.



  It can be seen from Figures 5 and 2 that while CPC successively compares the digits A and B, CPB compares the digits A and C. If it is still assumed that A is the number which is progressively registered in SRA, the CPA becomes ineffective at this moment in the sense that it only compares the number B with itself, since this number B circulates in SBR. If the number B were to get to SRB while the number A, which was previously recorded in SRA, was circulating through this register, it would be the comparison unit CPB which would only compare the number A with itself.



  Therefore, taking the case that A is introduced into SRA as an example, A is compared to B and C as the starting number. Regardless of the fact that the number B is not compared to the number C, the two comparisons see some indication or order between <I> A, B </I> and C, which can take six different forms if no consideration is given to cases of equality of digits. The reason that justifies the fact that the circulating number B is not actually compared with the outgoing number C is as follows: If the number A replaces the number C in SRA, the device BS4 indicates whether B is greater or smaller as C. These relationships apply accordingly with respect to the number C just leaving SRA.



  The bistable device BS4 is of course the same as the bistable device BS3 and holds the results of the comparison given by CPA by the fact that two of its inputs are connected through the gates G21 and G20 to the terminals P5A and P6A. In the same way, the inputs of BS5, which device displays the relationship between A and C, are connected to terminals P5B and P6B via corresponding mixing gates G22 and G23.



  Assuming that the BS4 registered the fact that B> C, it means that when the number B came into the SRB, it was found that B is greater than the number which left SRB at that time. If the number B has remained in the SRB from then on, this means that the number that is currently stored in the SRA is now leaving it, and that it is therefore smaller than B and greater than the number which previously left the SRB . From then on, all numbers that have passed through SRA cannot have decreased in value, but they must have remained smaller than B. If, on the other hand, BS4 indicates that C> B, this means that when B entered SRB, this number was less than the number leaving SRB at the time.

   If Bin SRB stops, it means that the number which is stored in SRA at that time has left this register and that it is therefore greater than the number that came out and also greater than number B, provided that the The number that went out and was replaced by B was at the same time not also greater than the number stored in SRA. Under this important condition, which will be reported on, the number that left SRA after Bin SRB was registered must be greater than B. Furthermore, the numbers that have passed through SRA since then cannot have decreased in value, and the number C, which now leaves SRA to be replaced by the number A, must therefore be greater than B.



  Therefore the above consideration proves that the state of BS4, that is to say B greater or less than C, gives a correct indication of the relationship between the number C, which is just leaving SRA, and the number <I> B, </I> which is stored in and circulating in SRB, regardless of the fact that BS4 has been flipped into its steady state while the number B has been compared with a different number than the one just exiting SRA.

   However, this consideration only applies if it is assumed that an outgoing number was never greater than the incoming number, but greater than the incoming number. Such a condition can of course arise, but the comparison device is provided with means which bring about an automatic return of the bistable device BS4 and BS5 when the displays are displayed there <I> C> B </I> and C> A are found.

    When such a condition is shown, BS4 and BS5 automatically become the states <I> B> </I> C and A> C offset. This automatic reset has already been mentioned above and is particularly advantageous in connection with the sorting with final comparison after the relay Adr or Bdr has worked. The main benefit of this automatic reset, however, is that it allows only one comparison process to be made between the incoming and outgoing number and between the incoming and the circulating number, while it prevents

   that a comparison process takes place between a circulating and an outgoing number.



  One notices that the consideration which justifies the comparison of only two pairs of numbers out of three is not complete insofar as the condition <I> B> C> A </I> is affected, as this may have resulted from the declared automatic reset after the number B in SRB and a number entering SRA were both found to be less than the number that left SRA at that time . However, if the number <I> B </I> stopped in SRB, this indicates that the number recorded in SRA at that moment was smaller than B.

   One is therefore led back to the general consideration that applies to the state B> C, since although all numbers that have passed through SRA can have increased values, they must still have remained smaller than B. Therefore the number C is which is now leaving SRA is actually less than B, as has been indicated by the state of circuit BS4.



  After the number A has fully entered SRA, the bistable devices BS3, BS4 and BS5 are put into corresponding states, creating the correct relationship between <I> A, B </I> and C is displayed. The circuit of FIG. 5 is there to sense these states in order to actuate one of the terminals PA or P and one of the terminals PC and PD, that is to say to provide them with a potential. This actuation is carried out by the differentiated trailing edge of the authorization pulse at terminal PO., Which appears at terminal P2.

         While the leading edge of this authorization pulse was used to prepare the circuit of FIG. 6 for the comparison process, the inverter 13 in FIG. 5 indicates that the differentiated trailing edge of the authorization pulse appears as an effective signal at the output of 13, which is connected to an input of the mixing gate G27. Since the output of G27 is connected to the input of three gates G24, G25 and G26, this output signal tries to go through one of these three Koinzi denztore. The first gate G24 has two further inputs which are controlled by BS4 and BS5, the first of which is <I> C> B </I> and the latter C> A indicates.

   The second gate G25 has two further inputs which are controlled by BS4, which indicates C> B, via the mixing gate G, 8 and by BS5, which indicates A> C. Similarly, the third port G26 also has two further inputs, those from BS4, which indicates B i C, and through BS5, which <I> C> A </I> can be controlled via the mixing gate G29. This means that gate G25 via G28 is alternately influenced by BS4, which indicates C> B, and BS3, which indicates B> A. In the same way, port G26 via G29 is influenced by BS5, which indicates C> A, and BS3, which indicates A> B.



  It should therefore be noted that if a pulse appears at the output of gate G27, only one of the three coincidence gates G24, G25 and G26 is ready to pass a pulse through.



  If the impulse is able to go through the gate G25, this means that the conditions are such that the number A corresponds to a document which should be brought into the switch position and to a starting position which is the same after which the C -Document has been transported. This also means that the next A document has to come from an A entry position so that its number is recorded in SR A. The output of G25 therefore forms the first input of the bi-stable device BS7 and the output terminal PA, which corresponds to the A state of BS7, is actuated.

   If it is the gate G26 which supplies an output pulse, it tilts BS7 in the same way into its B position, if it was not already in this position, and the terminal PB is actuated.



  If the pulse at the output of gate G27 is able to pass through gate G24, it means that <I> A </I> and <I> B </I> are smaller than C. It is therefore necessary to change the output either for the A document or for the B document. The appearance of this pulse at the output of G24 therefore does not indicate which of the documents A or B is to be conveyed forwards, but that whichever document has been advanced, it must take the direction that is in contrast to the direction which took the C document.



  This output pulse is given to the individual inputs of the bistable device BS6, which therefore works as a two-valued counter. If this was in state C, with terminal PC energized, it goes into D state, with terminal PD being actuated, and vice versa.



  In addition to being connected to the individual input of BS6, the output of G24 also leads to the inputs of the devices MS and MS4 which are provided with a stable position. The first of these devices has a time constant of 50 microseconds, and the second one of 100 microseconds. They serve as pulse delay devices for the pulse that appears at the output of G24.

   Approximately 50 microseconds after MS is triggered by a pulse from output G, 4, they can be returned to their stable state and generate a pulse which through the respective mixing gates G26 and G22, the devices BS4 and BS5 in the states cant that ads <I> B> C </I> and <I> A> C. </I> This is the reset process mentioned earlier.



  Another 50 microseconds later, the toggle switch MS4, which was released simultaneously with MS, generates a pulse through G, 7 through its automatic return to the stable O-position, which pulse is then sent to the three gates G .., 4, G, 5 and G26 is applied when the pulse at the output of 13 is led to these three coincidence gates.

   However, gate G24 is locked and G25 or G26 is unlocked. Therefore, the pulse generated by MS4 appears either at the output of G24 or at the output of G26, in order to put the device BS7 in the state which indicates which of the documents, <I> A </I> or <I> B, </I> should be brought into the switch position.



  Another input of the mixing gate G27 is connected to the terminal P3, which, as can be seen from FIGS. 2 and 3, can receive a pulse when one of the stack sorting relays Adr or Bdr is working to the terminal PL via the contacts <I> goodbye </I> or bd2 and via a differential circuit, which is indicated by a capacitor, to be connected to terminal P3.

   Therefore, this pulse, which is necessary because the last document in the entry position has not been replaced, simply examines the states of the comparator CP in exactly the same way as the pulse caused by the trailing edge of the authorization pulse at terminal P2 , the states of the comparison device examined after each comparison process.



  Such an impulse for sorting with final comparison naturally follows the opening of the connection between the terminals PBC and PD or PAC and PC, which caused the devices BS4 or BS5 to enter the state through the mixing gates G21 or G23 <I> C> B </I> or <I> C> A </I> to be moved.



  It should be noted that the device according to FIG. 5 is not used to determine on the basis of the states of the comparison units CPA, CPB and CPC whether the two numbers which it compared with one another are the same; However, each unit according to FIG. 6 can give such a display, since in this case the flip-flop BS2 remains in its state I after a comparison. However, a perception of such a condition of equality is not necessary. This means that if the numbers are compared in increasing order, not only the gate G13, but also the bistable device BS2 could be omitted. In this case, gate G14 can also be omitted.

   Furthermore, the device MS2, which is provided in each comparison unit, would then serve three comparison units together, since a single blocking of the comparison pulses arriving at a single comparison unit (CPC) would no longer be required. It would only be necessary for the comparison pulses to follow the timing pulses after a certain time interval, so that only one device MS provided with a stable position would be necessary.



  The correct operation of the device according to FIG. 5 in the event of equality between two numbers depends on the reset feature of the bistable devices BS4 and BS5 in the event that A and B are smaller than C.



  Two cases of equality can be considered. Either the incoming number in a register is the same as the number which is already stored in other registers, or it is the same as the number which it replaces in the named one register.



  When considering the case in which the numbers <I> A </I> and <I> B </I> have been compared with the outgoing number C with the result that A would be eliminated, let us first assume that the number <I> A ', </I> which arrives to the number <I> A too </I> replace, same <I> B </I> be. If <I> A </I> is removed, this means that the following states are present:
EMI0017.0010
  
    B. <SEP>> <SEP> A <SEP>> <SEP> C
 <tb> or <SEP> <I> A <SEP>> <SEP> C <SEP>> <SEP> B </I>
 <tb> or <SEP> <I> C <SEP>> <SEP> B <SEP>> <SEP> A. </I> If it is now noted that A 'equals B, the three conditions above lead to the following:

    
EMI0017.0011
  
     <I> B <SEP>> <SEP> A ' <SEP>> <SEP> A </I>
 <tb> or <SEP> <I> A <SEP>> <SEP> A ' <SEP>> <SEP> B </I>
 <tb> or <SEP> <I> B <SEP>> <SEP> A ' <SEP>> <SEP> A. </I> These three states can be achieved by considering z. B. the first to be proven. If <I> B> A </I> is given, this leads to B> A ', since the comparison unit CPC and in particular BS3 are in their previous state. On the other hand, the front budding leads <I> B> A </I> Condition for A '> A, <I> because B = A ' </I> is.

   It can therefore easily be stated that the three possible conditions which are obtained after the introduction of A '= B in SRA are such that either the A' or the B document is pushed forward, which does not matter Which of the two, however, that the B-document is conveyed in the other direction to that which has taken the A-document, in the case that A was greater than C, which number in turn was greater than B.



  Indeed, three conditions that have been considered above include that in which <I> C> B, </I> which in turn is greater than A. This condition cannot apply if the provision is applied. The automatic reset generates in their place <I> B> A> C. </I> Therefore, if an incoming number is equal to the number already stored in the other register, with or without automatic reset, regardless of the lack of an equality check in the current comparison, that number is treated correctly.



  Now considering the case in which <I> A '= A </I> are the three possible conditions for which <I> A ' </I> in place of the lost <I> A The same occurs as before, but given the equality between <I> A ' </I> and <I> A </I> the corresponding conditions can be derived:
EMI0017.0021
  
     <I> B <SEP>> <SEP> A ' <SEP>> <SEP> A </I>
 <tb> or <SEP> <b> <I> A,> </I> </B> <SEP> A <SEP>> <SEP> B
 <tb> or <SEP> <I> B <SEP>> <SEP> A <SEP>> <SEP> A '. </I> These can for example be explained by the preceding condition <I> B> A> C </I> is considered. On the one hand leads <I> A> C to A '> A, </I> because the comparison unit CPB and in particular BS is in its previous state.

   On the other hand, because of the equality between <I> A> A ' </I> the state <I> B> A </I> to B> A '.



  In the first two cases, the A 'document necessarily follows the A document in the same direction. In the third case, the B document would follow the A document. However, this would not be correct because it says that anyway <I> A '= A </I> and the A 'document is not allowed to follow the A document even though it is smaller than B but not smaller than A.

   This case is automatically replaced by the first one who then lets the system work properly.

 

Claims (1)

PATENT CLAIM Electrical sorting system for objects, in which numbers on the latter are electrically perceptible represented numbers are sorted by dual comparison processes, with a pair <I> (SA, SB) </I> originally with respect to the numbers of randomly ordered sequences of objects in several Operations is converted into a new pair <I> (SC, SD) </I> of differently ordered sequences and a comparison operation extends to at least two objects <I> (A ', B') </I>, each of which from removed from another original sequence, characterized in that two electrical shift registers (SRA, SRB) with at least <I> n + </I> 1 levels each, where <I> n </I> is the number of binary digits required to identify any of the numbers that the two registers are used for to register the number of an object from the first (SA) or second <I> (SB) </I> original sequence, so that when a new number <I> (A, B) </I> from one of the original sequence of numbers is progressively introduced into one of the registers, it is compared digit by digit with the number (C) that was previously stored in this register and the progressively exits from the named register that the named new number <I> (A </I> or B) while it is being introduced into the named register, it is simultaneously compared digit by digit with the number <I> (B </I> or <I> A) </I> which has previously been stored in the other register and that continuously circulates through this, and that means (BS3 BS5) are available which, as a result of the comparison, register the order of the relative size of the numbers (A, B, C), and that depending on this order one of the objects is one of the new sequences <I> (SC, SD) </I> is supplied, after which the said comparison process occurs when an object is supplied from an original sequence <I> (SA, </I> <I> SB) </ I > repeated as long as until an original sequence is processed. SUBClaims 1. Sorting system according to claim, characterized in that first (BS3), second (BS4) and third (BS5) bistable devices are provided in order to display the results of the comparison processes between <I> A </I> and <I> B, B </I> and C or <I> A </I> and C to register that each of the mentioned bistable devices is toggled into one or the other state, depending on which one of the corresponding numbers is greater or less than that others that a first (G24), a second (G25) and a third gate (G26) is provided, the first gate being able to provide an output signal after said second and third bistable means together indicate that C is the last number of a sequence of one of said new sequences that the second gate is able to give an output signal to said bistable devices which together indicate that A should continue the sequence which already contains at least C, that the third port is able to give an output signal after said bistable devices together indicate that B should continue the sequence that already contains C, that the signal supplied by said first gate (G24), a fourth stable device <B> (A ") </B> triggers, which acts as a two-valued counter and whose two stable positions correspond to said first or second new sequence, that the signal that either from the second or from the third gate is delivered, a fifth bistable device (BSG) moves into one or the other of its stable positions, which corresponds to <I> A </I> or <I> B </I>, which must continue the sequence. 2. Sorting system according to dependent claim 1, characterized in that said output signal, which is supplied by the first gate (G24), causes the states of the second (BS4) and third (BS @) bistable devices to be reversed <B> (MS., < / B> G26, G22) and that when said first port provides an output signal, said second (G25) and third (G26) ports can only provide an output signal after said reversals have been carried out. 3. Sorting system according to dependent claim 2, characterized in that said second (BS4) or third (BS5) bistable device is kept permanently in that state which allows the first gate (G24) to emit an output signal after all numbers have been one of the original sequences have gone through the corresponding register, with any remaining numbers of the other of the two sequences mentioned being stored according to their original sequence. 4th Sorting system according to claim, characterized in that the two registers (SRA, SRB) are set to an initial number (0) before the sorting process is started, this in such a way that the introduction of the first number of one of the original sequences <I> (SA , SB) </I> in one of the mentioned registers shows that the first number of the other original sequence is introduced into the other register.