CH554749A - TYPEWRITER WITH ERASING DEVICE. - Google Patents

Description

  

  
 



   The invention relates to a typewriter with an erasing device for erasing characters that have already been printed and with a printing unit, a keyboard, a step and backward switching device.



   When typing, the problem has always been of removing incorrectly printed characters and replacing them with correct characters. To solve this problem two approaches have essentially been taken. On the one hand, the faulty characters by shaving by means of mechanical devices, such as. B. rotating erasers or the like, or on the other hand by covering with dye or tearing off the printing ink from the paper using adhesive tape. In all cases, the operator had to position the extinguishing device precisely and to control the extinguishing process in detail via the corresponding operating elements.

  The above-mentioned methods are feasible if it is a question of replacing a single character, but they are very cumbersome and time-consuming, for example if a forgotten word has to be inserted and the space required for this has to be created by shaving a larger part of the text and the operator must remember the erased words separately in order to use them again later.



   This was remedied by the introduction of typewriter systems with magnetic tape storage, be. * The deletion and insertion of text by adding and reordering the contents of the magnetic tape storage is easily possible, although a fair copy is only obtained in the second pass. Typewriter systems of this type are naturally extremely complex and therefore expensive.



   The present invention is concerned with improving typewriters of the first mentioned type, i.e. typewriters. H.



  the typewriter with erasing device for erasing characters that have already been printed, as well as with printing mechanism, keyboard, step and backstep switching device, and with means for transmitting signals assigned to the machine operations and with signal input means for receiving signals for controlling the machine operations.

  The typewriter according to the invention is characterized by a memory designed to store a plurality of character bytes, each of which is assigned to a printing position and can contain information relating to the character to be printed at this printing position, a queue control device for identifying individual bytes in the memory in accordance with the sequence of the print positions to which the characters correspond, a keystroke recording control device which is controlled by the keyboard and the queue control device to write character bytes in the memory in an order corresponding to the associated print positions, operating parts for initiating an erase operation, and by circuits for Controlling the delete operation,

   comprising a generator for outputting erase signals to the printing unit, and a sequential repetition circuit which is effective with each erase operation in order to switch on the backstep switching device and to initiate a further erase operation.



   Details of the invention are explained in more detail below with reference to an exemplary embodiment shown in the drawings.



   In the drawings show:
1 is a block diagram with the main components of a preferred embodiment of the invention,
Fig. 2 is a schematic representation of a character byte,
3 to 8 flow charts of different workflows of delete operations,
9 shows a delete key arrangement,
FIGS. 10 and 11 are flow charts of various work sequences in a delete operation.



   1 shows a typewriter 10 which is set up to generate electrical signals which correspond to the actuation of the keyboard and which can be operated both by electrical input signals and by actuating the keyboard. Typewriter 10 includes devices for performing all typewriter functions. The most important devices in connection with the present invention are the following:
A serial printing unit 11 which prints characters 12 at a printing position 13 on a recording medium 14, a stepping device 15 which shifts the printing unit 11 and thus the printing position 13 to the right to further printing positions 16, 17, 18 etc. within the printing line 19, and a backspace switch device 20 for shifting the print position back along the print line 18.

  In addition, the typewriter 10 has a switching device 21, which permits the printing of upper and lower case letters, and a write suppression device 22, as described, for example, in US Pat. No. 3,592,309.



   The typewriter 10 has a keyboard 30 with a group of character keys 31, a space key 32 for controlling the stepping device 15 independently of the printing of characters, a backspace key 33 for actuating the backspace switching device 20, a shift key 34 for actuating the switching device 21, a Return key 35 to return the print position 13 to the left edge and at the same time advance the recording medium 14 to a new print line, and with a tab key 36 to continuously shift the print position 13 to the right along the print line 19. Pressing the keyboard 30 causes electrical signals to be generated on lines 37, to which a data line 38 belongs.



  Signal lines 23 are also provided, via which control signals can be fed to typewriter 10.



   The typewriter 10 also has an ink ribbon transport device 24 as well as a character erasing device which comprises an erasing tape transport device 25, as is described, for example, in German Offenlegungsschrift 2 164 748. The erasing tape transport device 25 is actuated by pivoting a rail 26 from its position shown in FIG. 1 and lifts an erasing tape 27 so that it is aligned with the printing position 13, while the printing unit 11 prints the type of character to be erased again. The erasing tape 27 is gradually transported further after each erasing operation, so that an unused piece of erasing tape is available for each new erasing operation.

  The erasing tape 27 can either be coated with a white opaque transfer compound with which an erroneously printed character can be covered, or with an adhesive layer with which the dye of the erroneously printed character can be lifted from the recording medium 14. In both cases, the mark is completely removed by printing the corresponding type on the back of the erasing tape.

 

   Since it is normally desirable to print a correct mark at the location from which the wrong mark was removed, the rail 26 is connected to the indexing device via a handlebar 28. to lock them during a delete operation. An electromagnet is connected to the rail 26 in order to bring it into its working position when a corresponding electrical signal is received.



   With the typewriter 10 a memory 40 is connected to the recording of bytes 41, which represent character information which is assigned to the individual print positions and to retrieve these bytes 41 in an orderly sequence according to the progress of the print position 13 along the print line 19. FIG. 2 shows a simplified example of the content of a byte 41 stored in the memory 40. The byte 41 comprises eleven binary bits, which are designated B1 to B11. The bits B1 to B9 serve to identify the character which is to appear on the recording medium 14. Of these bits, bit B7 indicates whether the character to be printed belongs to the character set corresponding to upper case or to the character set corresponding to lower case.

  Bits B1 to B6 identify the relevant character within the selected character set. Bit B8 indicates whether the character should have an underline. Bit B9 indicates whether the character is actually to be printed or whether it is a space, such as a space between words. Bit 10 indicates whether the entire byte 41 contains useful information or is empty. Finally, bit B11 indicates whether the relevant character is actually present on the recording medium or whether it has been erased and is ready to be overprinted. As already mentioned, the configuration of byte 41 is shown somewhat simplified for the purpose of explanation.

  Thus, single bit storage is shown to identify whether there is useful information, or whether it is a space and whether the character has been printed; however, it is clear that this information can be encoded in such a way that the total number of bits required to store a corresponding amount of information is reduced. The memory can preferably be a monolithic memory, such as is used in printed circuits, but it is readily possible to use any other type of memory, such as e.g. B. to use a core memory or even to some extent a magnetic tape.



   The memory 40 has sufficient storage space for the greatest number of print positions that can occur within a specific text section. If the text section comprises a print line within which corrections are to be made, a storage space of 128 bytes in the memory 40 would slightly exceed the number of print positions in a normal print line. The memory 40 is connected to a queue control device 42 which monitors the sequence of the bytes 41 within the memory 40. Since both the required memories 40 and the corresponding queue control devices 42 are sufficiently known, details of these are not discussed here.

  It suffices to point out that the queue control device 42 can identify the next byte 41 in each case and progressively further bytes in ascending or descending order by appropriate changes in the numerical identification. In order to select different bytes, signals can be generated which advance the control device 42 by one step via a line 43 or cause the control device 42 to switch back via a line 44. The current state of the control device 42 can be read off via lines 45 or a completely new state can be brought about. The control device 42 signals its upper and lower limit values via lines 46 and 47.



   To correlate the operation of the typewriter 10 with that of the memory 40, a control unit 50 is provided, which is made up of circuits that can be divided into a clock 51, a status memory 60 for the temporary storage of information relating to the various operating conditions for the control of the current operation is necessary, and a switching circuit 52 that makes sequential decisions and sequential commands in an order determined by the operation of the clock 51 and based on the information present in the typewriter 10, in the memory 40 and in the state memory 60, gives.

  In addition, suitable circuits 53 are provided for generating typewriter control commands, as well as a read / write circuit 54 for the memory, which is connected to memory 40 via lines 55. Details of the circuits are known and since they do not form part of the present invention they are not described in any further detail. It should be pointed out that instead of special circuits such as those used for an exemplary embodiment, a suitably programmed computer can also be used to carry out the corresponding functions.



   The state memory 60 comprises holding circuits for storing the information relating to the operating mode and the characters. An erase hold circuit 61 is set by a primary erase signal on line 61a to initiate an erase operation. A word hold circuit 62 is set by a secondary clear signal on line 62a and indicates whether an erase operation is word length. The secondary erase signal on line 62a also sets a line hold circuit 63 which remains switched on after a word erase operation has been completed to indicate that the erase operation should be line length.

  An erasure process for a single character is initiated by setting the erase hold circle 61 without setting the word hold circle 62 and the line hold circle 63. Thus, the three hold circles 61, 62 and 63 can represent three different states, namely the deletion of a line if the hold circles 61 and 63 are set, the deletion of a word if the hold circles 61 and 62 are set and the hold circle 63 remains in the idle state, and the deletion of a character if only the hold circle 61 is set. A delete only hold circuit 64 is set by a signal on a line 64a and causes characters deleted on a page of text to be stored in memory 40 for later retrieval and printing.



  In the normal state, the hold circuit 64 has the effect that the characters released on a page of text are removed from the memory 40 at the same time. Another hold circuit 65 is set by a signal on line 65a when a rewrite operation is in progress.



   In addition to the latch circuits described, the status memory 60 contains a plurality of registers for the storage of information consisting of a plurality of bits which are required for control purposes. These registers include a keystroke register 66, a memory input / output register 67 and a register 68 for storing the current print position. The register 66 is connected to the data output lines 38 of the keyboard and stores a byte of information which corresponds at least to the information contained in the bits B1 to B9 of the byte 41 in the memory 40.

  Register 67 can be connected to memory 40 under the control of queue controller 42 to receive from memory 40 a single byte 41 of character information or to write a single byte of character information into memory. The register 67 can also be connected to the circuit 53 to control the typewriter 10 to perform printing operations for rewriting or erasing characters and for space-step operations. The register 68 can be connected to the control device 42 via the read / write circuit 54 in order to record the current printing position of the typewriter 10 and to reset the control device 42 so that it corresponds to the current printing position.



   The switching unit 52 has groups of circuits for executing various control sequences, including decision circuits, which are connected to the typewriter 10, the memory 40, the control device 42 and the status memory 60 at certain times in accordance with the clock 51 in order to determine whether to a certain state prevails at the time in question. Circuits are also provided which monitor the generation of command signals and the existence of conditions for the initiation of various operations of the typewriter 10, the state memory 60, the control device 42 and the memory 40 at times determined by the clock 51.

  The specific electronic components and circuit arrangements required for these purposes are well known or can be readily constructed with knowledge of the decisions to be made. In FIG. 1, these circuits are divided into individual primary sections, namely a circuit 56 for recording a keystroke, a circuit 70 for controlling an erasing process and a circuit 80 for controlling a rewriting process. The circuit 56 comprises a memory output circuit 57 and a detection circuit 58 for detecting the presence or absence of a bit B11 (character does not appear) in the register 67. The circuit 70 has a memory tracking control circuit 71, which has a memory input circuit 72, a termination circuit 73 and a print sequence control circuit 74.

  The circuit 73 has the following circuits: a logic circuit 75 for repeating a sequence, a logic circuit 76 for determining that the deletion of a word has been completed, a logic circuit 77 for determining that the deletion of a line has been completed, a logic circuit 78 for determining that the deletion of a character has ended, and a logic circuit 79 for inhibiting a repetition. The print sequence control circuit 74 is common to the circuits 70 and 80. The circuit 80 also has two logic circuits 81 and 82 which are provided for the repetition of a rewrite sequence or for the blocking of such a repetition.



   Details of said sequence control circuits are determined by the sequences to be processed, which are shown in the form of a flow chart.



   A keystroke recording (Fig. 3 to 5) is initiated by the operator by pressing one of the characters 31 or the space bar 32 of the typewriter 10. While the typewriter performs its own print and index cycle, the keyed in information is transmitted over the output line 37 and stored in the keystroke register 66 by operation 90.



  The current position of the print position 13 along the print line 19 is stored in the register 68 by means of operation 91, in which the current numerical status of the queue control device 42 is transferred to the register 68. The current printing position can also be stored within the typewriter 10 itself by providing a printing position transducer which is able to identify each individual printing position along the printing line. In operational step 92, the information contained in byte 41 of memory 40 identified by control device 42 is read out as corresponding to the current printing position of the typewriter and is read into memory / input / output register 67.



   When information is initially keyed into a new print line, no significant information is entered into register 67 by operation 92. When the conditions for storing the keystroke are entered, it is determined by the circuit 58 by means of the decision 93 whether the byte in the register 67 does not contain the bit B11 character appears, i. H. in other words, whether the information byte possibly removed from the memory 40 is intended for later rewriting.



  Since, upon initial keying in of a line of text, the determination based on the lack of information in register 67 is negative, the operation proceeds to decision 100 (FIG. 4) wherein it is determined whether register 67 contains any useful information. At the initial keying in, no information is stored in register 67 and consequently operation 101 is passed, in which the content of register 66 is written as significant information that appears on the printed page in that byte 41 of memory 40 which is controlled by the control circuit 42 is designated. In operation 102, the control circuit 42 is then advanced by one unit so that it corresponds to the printing position 13 which results after the typewriter has completed the printing and indexing operation.

  The sequence is completed by operation 103 in which the keystroke register 66 is reset so that it no longer contains any information. The switching mechanism 52 reacts to actuation of the return key 35 or the tabulator key 36 by resetting the control device 42 to its lower limit value and all bytes 41 in the memory 40 to empty. If the typewriter 10 is equipped with a transducer that identifies the discrete print positions, tab reset is not required.



   If the first keystroke adds characters to a part of a print line 19 in which there are previously deleted characters which were not marked in bit B11 with characters appears, decision 93 passes to decision 94 (FIG. 3), in which it is determined whether the control device 42 has reached its upper limit value, which means that the capacity 40 is fully utilized. This determination directs the sequence over to operation 101 (FIG. 4), which causes the keyed-in information to replace the information previously stored in the last available byte 41 if, as is usually the case, is determined by decision 94 that the control device 42 has not yet reached its upper limit value.

  A memory output operation takes place under the control of circuit 57, the previously stored but deleted byte 41 being connected upstream to the next adjacent higher position in memory 40. This sequence begins with shifting the previously stored byte in the highest digit to the next higher digit and repeating the shifting process until all bytes with a higher value than the current print position have been shifted. The sequence begins with operation 110 (FIG. 5), with the controller 42 set to its upper limit. Operation 111 moves the control device 42 back by one step in order to address the byte 41 in the second highest position in the memory 40. With operation 112, byte 41 addressed in this way is transferred to register 67 for temporary storage.

  Operation 113 advances control device 42 by one step and operation 114 transfers the temporarily stored byte from register 67 to byte 41 in the next higher position in register 40, which is now identified by control device 42. Operation 115 sets the control device 42 back again by one step in order to address again the byte 41 in the memory 40 from which information has just been shifted to a higher position.



   The decision 116 compares the address in the control device 42 with the current printing position, which is stored in the register 68, in order to determine whether the control device 42 is now addressing the byte 41 which corresponds to the current printing position 13. If this is not the case, the sequence is returned to operation 111, the next adjacent byte 41 being shifted to a higher position in the memory order. After each shifting process, a decision 116 follows, until it finally determines that the control device 42 with the in the register
68 stored current print position is in agreement. The output operation is thus ended and the sequence returns to operation 101 (FIG. 4), the keystroke information being transferred from the register 66 to a byte 41 of the memory 40 which has now become empty.



   If at decision 100 (FIG. 4) it is determined that useful information is stored in register 67, the sequence advances to decision 104, which determines whether keystroke register 66 contains a space. If this is the case, the operator has switched the printing position 13 one step upstream, and operation 102 can thus be passed directly to keep the control device 42 in accordance with the printing position 13 which has now been advanced. However, if the operator has struck a character key, a transition is made from decision 104 to decision 105, in which it is determined whether the information contained in register 67 corresponds to a space.

  When the sequence has progressed to this point, the determinations so far indicate that the operator is writing a new character over a previously stored but not erased character. This is only permissible if the previously stored and not deleted character is a space, in which case, as determined by decision 105, a return is made to operation 101 in order to save the keystroke. However, if the operator should actually attempt to write a character over a character that has already been printed, then decision 105 leads to operation 106 in order to immediately switch on the write suppressor device 22, which blocks printing, but not progression. The sequence then returns to operation 103 to set register 66 to empty.

  In this way, the operator is prevented from spoiling the page of text by overprinting new characters over previously stored and non-deleted characters.



   A deletion sequence is initiated by the operator if an error has occurred within the current line of text. In most cases the mistake will affect the last character written, but the sequence to be described allows correction of mistakes found in the middle of correct text. If an error has been detected, the operator must first decide whether the characters to be deleted should be stored in the memory or whether they should be removed.



  In the normal course of the sequence, the erroneous characters are both erased from the printed page of text and removed from memory. The operator therefore has nothing to do, unless the characters to be deleted are to be printed again later, in which case the operator switches a mode switch 120 from its normal position delete and remove (FIG. 1) to its position delete only before she actuates the delete key 121 (FIGS. 1 to 9).



   9 shows a preferred embodiment of a delete key with a key lever 122 which is held by a spring 123 against a stop 124 in its normal rest position. Switches 125 and 126 are arranged below the button lever 122. In addition, a displaceable stop 127 is provided under the key lever 122, which is held so far upward by a spring 128 that a distance 129 results over which the key lever 122 can be moved without hitting it. The type lever 122 closes the switch 125, but the switch 126 remains open. Only when the button lever 122 is pressed down further against the force of the spring 128 is the switch 126 also closed.



  The switches 125 and 126 are connected to the erase hold circuit 61 and word hold circuit 62 via lines 61a and 62a, respectively.



   Closing the switch 125 causes the erase hold circuit 61 to be set (operation 130, FIG. 6), whereby the electromagnet 29 attracts and the rail 26 pivots, whereby the erase tape 27 is prepared for lifting and transporting during the subsequent printing process. As already mentioned, the stepping device 15 is blocked by the link 28 fastened to the rail 26, so that no stepping operation can take place during the following printing cycle. The hold circuit 61 also initiates the erase control sequence. Closing the switch 126 sets the hold circuit 62, which means that the erase process comprises a whole word length.

  In the following operation 131, the byte 41 identifying the character, which corresponds to the current printing position of the typewriter 10, is transferred from the memory 40 into the register 67 under the control of the control device 42. Decision 32 determines whether the character transferred into register 67 is a printable character, and in this case a print cycle is initiated under the control of print sequence control circuit 74. The print cycle (FIG. 7) begins with decision 140 and the determination of whether the information contained in register 67 is marked with a bit B8, which would mean an underline. If the character is not underlined, then decision 141 determines whether the character in register 67 is identified by a bit B7 as being to be printed in upper case.

  If this is the case, decision 142 is used to examine whether typewriter 10 is set to upper case. If this is the case, operation 143 is carried out directly, a driver generating a print command in circuit 53 and outputting it to typewriter 10, so that typewriter prints the character taken from memory 40. Since the electromagnet 29 has already attracted under the control of the erase hold circuit 61, this print command for the typewriter 10 actually has the effect of an erase command. If the decision 142 had shown that the typewriter 10 was not set to upper case, the operation 144 for switching to upper case would have been carried out before operation 143. Only then would the print-delete command have been transmitted.

 

   The procedure is similar if the character in register 67 is not capitalized due to the determination by decision 141. Decision 55 then determines whether the typewriter is currently set to lower case. If so, the print clear command (operation 143) is issued. If decision 145 determines that typewriter 10 is not currently set to lower case, operation 146 follows to actuate toggle 21 and set the typewriter to lower case prior to issuing the print erase command of operation 143.



   If it is determined by decision 140 that the character transferred from memory 40 to register 67 has an underscore identifier in bit B8, a transition is made to decision 147 to determine whether the typewriter is currently set to upper case, since the underscore character is normally upper case listened to. If the typewriter is not set to upper case, the switching device 21 is actuated in operation 148 and the typewriter is set to upper case. Otherwise, the sequence proceeds directly to operation 149 and issues an underline print command before proceeding to decision 141.



   Simultaneously with the deletion of characters on a text page by outputting the delete pressure lever as described, the present invention provides the possibility of introducing the information character does not appear in bit B11 of byte 41, or if so, by a memory tracking control circuit 71 an erase and remove operation is required to insert no useful information in bit B10, freeing byte 41 for another record. If a character has been deleted and removed and bytes 41 remain in the line which represent characters of a higher order (ie further to the right in the line), these are automatically transferred to the next lower order digits by the input circuit 72 of the memory tracking control circuit 71 moved within the memory 40.

  The follow-up operation for memory 40 begins with decision 150 (FIG. 8), where the current state of delete-only holding circuit 64 is checked. Normal operation is delete and remove, so that a transition is made from decision 150 on the no side to operation 151, with information being stored in bit B10 which indicates that byte 41 identified by control device 42 is empty and not useful information contains more.



   The insertion sequence begins under control of input circuit 72 with operation 152, with controller 42 advancing to the next higher address. Byte 41 addressed in this way is transferred to register 67 in operation 153. With decision 154 it is clarified whether the control device 42 has reached its upper limit value, which means that there are no higher-order bytes in the memory 40. If the control device 42 is not at its upper limit value, it is determined with the decision 155 whether the byte now addressed is marked as empty in its bit B10.

  If decision 155 determines useful information, controller 42 is moved back one step in operation 156 to the immediately adjacent lower order byte which byte was originally freed by operation 151. The byte 41 removed in operation 153 is now transferred in operation 157 to the newly addressed byte 41 in memory 40, and operation 158 advances control device 42 by one step to the next higher-order byte in memory 40.



   The sequence is then returned to operation 152 and repeated until either the decision 154 determines that the control device 42 has reached its upper limit value, or it is determined in the decision 155 that an empty byte was addressed in the operation 153. In either case, the tracking operation is completed by moving to operation 160 in which the controller 42 is reset to the current printing position stored in register 68. The byte 41 of the memory 40 now identified by the control device 42 is transferred to the register 67 (operation 161). A termination sequence is performed under control of circuit 73. Decision 170 (FIG. 10) determines the state of hold circuit 63.

  If this hold circuit 63 associated with the deletion of a line has not been set, the sequence proceeds to decision 170 in order to determine the state of the word hold circuit 62. If the operator has set the delete button 121 to its second position with both switches 125 and 126 closed, the latch 62 indicates that a word delete operation is selected and the sequence advances to decision 172 which the controller 42 reviews the logic circuit 77 is checked whether it is at its lower limit value, which means the beginning of a new line. If the control device 42 is not at its lower limit value, it is switched back by one step (operation 173) in order to address the next lowest byte 41 (closer to the beginning of the line).

  The newly addressed byte 41 is transferred from the memory 40 into the register 67 with the operation 174. With decision 175, the state of the word holding circle 62 is again checked and, provided that the delete key 121 is fully depressed, the logic circuit 76 determines in decision 176 whether the byte 41 removed from memory 40 in operation 174 is a space . Incidentally, this byte coincides with the position immediately to the left of the character deleted at the printing position 13 due to the delete command of operation 143.

  If there is no space in register 67, at least one more character within the word must be deleted and as a result the sequence repetition circuit 75 causes a backspace command to be generated in operation 177 in order to shift the printing position of the typewriter 10 one place to the left and the Control device 42 to step back one step in operation 178 to maintain its correspondence with the current print position. The whole sequence is thus returned to operation 131 and repeated until decision 176 determines that an empty step was taken from memory in operation 174, in which case the sequence passes to decision 180, in which the current position of switch 126 is checked becomes.

  If the operator has held the delete key 121 in its fully depressed position during the deletion of all characters, the holding circuit 63 is set on the basis of decision 180 by operation 181. The sequence then returns to operation 177 to repeat the deletion process again. The one-line erasing mode is thus set by the operator by depressing the erase key 121 while an entire word is being erased completely.



   If, however, the cancel button 121 is fully pressed down to close the switches 125 and 126, but then released again, it is determined by the decision 180 that the switch 126 is not closed, and then the logic circuit 77 in the operation 182 of the hold circuit 62 is reset to its normal state, in operation 133 (FIG. 6) the hold circuit 61 is reset when the hold circuit 64 returns to its normal clear and remove state, and in operation 134 the clear mode is reset.

 

   If the operator presses the delete key 121 only as far as it will go 127, only the switch 125 is closed and the hold circuit 62 is therefore not set. The sequence therefore initially proceeds as described, until decision 171 is reached. The check of the hold circuit 72 then gives a negative answer and the sequence goes to the decision 183 (FIG. 10), in which the byte 41 corresponding to the current print position, which was addressed in the operation 161, is checked by the logic circuit 78 whether it is a space. If it is not a blank step, the continuation of the operation is unnecessary and the sequence is terminated by the logic circuit 79 which initiates the operations 133 and 134.

  Had the operator decided to delete a single character after the character was printed and hit the space bar, decision 183 would have determined the presence of a space at the current print position and sequence retry 75 would have affected operations 177 and 178 so that the individual character would have been deleted by repeating the entire sequence.



   If the hold circuit 63 has been set in operation 181 as described, the entire sequence is repeated, with decision 170 directing the termination phase in such a way that decision 171 is skipped. Decision 172 thus ends the sequence when it is determined by logic circuit 77 that control circuit 42 has reached its lower limit value, whereupon logic circuit 79 executes operation 184 to reset hold circuit 63 and the sequence with operations 182, 133 and 134 to finish.



  If desired, additional circuitry may be provided which is responsive to a second actuation of the clear key 121 during a line erase operation to reset the hold circuit 63. This would allow the operator to interrupt a line erase operation when the erasing of the word during which key 121 was pressed again is completed.



   If the operator wants to delete correctly written characters in and of itself in order to get to a print position further to the beginning of the line for the purpose of inserting a forgotten word, the mode switch 120 is pressed before pressing the delete key 120, so that the delete sequence proceeds as described , with the exception that the delete only hold circle 64 is set. The state of the hold circuit 64 is determined by the decision 150 and the sequence is diverted to the operation 163, in which the information character does not appear is written into the bit B11 of the byte 41, which is determined by the control circuit 42 as the printing position of the operation 143 erased character is designated accordingly. After operation 163, the follow-up sequence is bypassed and circuit 73 executes the termination sequence.

  As previously mentioned, the completion of any sequence includes operations 133 and 134. In operation 133, the hold circuit 64 is returned to its normal clear and remove state.



   If an erase sequence is initiated when the print position 13 is set to either a space or a character that has already been erased, decision 132 transfers to decision 185 (FIG. 10), in which it is determined whether the byte in register 67 has a Represents an empty step which does not require a deletion process, and, if applicable, an immediate transition is made to decision 150. If decision 185 determines that the byte in register 67 is not a space, the sequence retry circuit controls operations 177 and 178 to switch the print position back, step back the controller, and start the entire sequence with operation 131 again .



   After an error has been corrected, the button 190 (rewrite) can be actuated in order to set the hold circuit 65 with operation 191 and thus initiate a rewrite sequence which is under the control of the circuit 80. In operation 200, under the control of the control device 42, the byte 41 corresponding to the current printing position is read from the memory 40, and in decision 201 the logic circuit 81 determines whether the addressed byte contains useful information, or the logic circuit 82 whether the addressed byte is empty. If the error has been corrected in the middle of a line which has either been skipped or deleted and which is unmarked in memory 40 with characters appearing, decision 201 indicates that useful information has been found and the sequence advances to decision 202.

  Bit B11 of byte 41 is checked to determine whether register 67 contains a character that has not been printed because it was previously deleted. The recognition of the character does not appear bit passes to operation 203, in which the character does not appear bit is removed from that byte 41 in memory 40 which is marked by control device 42 as corresponding to the current print position. The sequence then advances to decision 204, in which bit B9 of byte 41 in register 67 is checked to see whether it is a blank step. If the byte 41 is not a space, a print operation is initiated under the control of the print sequence control circuit 74, which print operation is identical to that performed in the erase sequence.

  This sequence begins with decision 205, which corresponds to decision 140, to determine whether the byte in register 67 contains underline information in its bit B8. The printing operation is terminated by operation 206, which is identical to operation 143, with the exception that the hold circle 61 is not set during this printing operation, and operation 206 thus causes normal printing of the selected character with the usual ribbon.



  The other operations within the printing sequence are identical to those already described and are not explained further here.



   After operation 206 has been carried out, operation 207 advances control device 42 to the next higher byte 41 of memory 40, and the sequence returns to operation 200, in which a new byte 41 is addressed. The sequence is repeated by the logic circuit 81, unless the circuit 82 detects an empty byte. If it is determined in decision 202 that the useful information determined in decision 201 is not character does not appear, the information obtained is interpreted either as a space on the text page or as a character which remains printed on the text page from a previous printing operation .

  In either case, the sequence proceeds to operation 208, in which a step command is issued to the typewriter 10, and to operation 207, in which the controller 42 is incremented to the next higher byte 41 in memory 40 before the sequence begins operation 200 returns. The process is the same if decision 204 determines that byte 41 identified by decision 202 is recognized as a space on the page and only requires an operation 208 instead of a printing operation beginning with decision 205.

  It is thus clear that after the key 190 (rewrite) is pressed, the typewriter steps along the typing line to reprint those characters that were previously erased but not removed, and that it switches over those characters without printing the remain on the recording medium from a previous printing process. This sequence is repeated until it is interrupted by circuit 82 in decision 201 which, by checking bit B10 of byte 41 in register 67 (operation 200), determines that there is no longer any useful information at the current printing position . The sequence is then terminated by operation 209 which resets the hold circuit 65 to its normal rest position.

 

   The sequences for erasing and printing processes mentioned in the exemplary embodiment described can also be programmed for a general-purpose computer which is connected to a printer which has suitable printing and erasing devices. The typewriter described in connection with the exemplary embodiment erases characters by selecting the character to be erased again with subsequent overprinting, but already known machines with a rotating eraser can also be used, and the present invention can be applied to these machines in the same way.

 

Claims (1)

PATENT CLAIM Typewriter with erasing device for erasing characters that have already been printed, as well as with printing mechanism, keyboard, step and backward step switching device, and with means for transmitting signals assigned to the machine operations and with signal input means for receiving signals for controlling the machine operations, characterized by a memory (40), designed for storing a plurality of character bytes (41), each of which is assigned to a printing position (13) and can contain information relating to the character to be printed at this printing position (13), a queue control device (42) for identifying individual bytes (41) in the memory (40) in accordance with the order of the print positions to which the characters correspond, a keystroke recording control device (56), which is controlled by the keyboard (30) and the queue control device (42) to write character bytes (41) in a sequence corresponding to the assigned print positions in the memory (40), operating elements (120, 121) for initiating a delete operation and by Circuits (61 ... 64, 70) for controlling the erase operation, comprising a generator (53) for outputting erase signals to the printing unit, and a sequential repetition circuit (75) which is effective for each erase operation to control the step-back switching device (30) to switch on and initiate another delete operation. SUBCLAIMS 1. Typewriter according to claim, characterized in that the circuits (61 ... 64, 70) for controlling the erase operation comprise a circuit (73) for terminating the erase operation, the at least one first circuit (76, 77) for determining the Completeness of the deletion of all characters to be deleted of a word and / or a line and a second circuit (79) which, depending on the first circuit (76, 77), blocks the further operation of the repetition circuit (75). 2. Typewriter according to claim, characterized in that the operating parts (120, 121) interact with switches (125, 126) which determine the operating mode and which have a first state, in which the erase operation corresponds to a character length, and a second state , in which the erase operation corresponds to a word length, that the circuits (61 ... 64, 70) comprise a termination circuit (73) with a first recognition circuit (78) for recognizing the completeness of a character erase operation, with a second recognition circuit (76 ) for recognizing the completeness of a word delete operation and with a blocking circuit (79) which, controlled by the switches (125, 126) and by the detection circuits (78, 76), blocks the further operation of the repetition circuit (75): at the end of a character erase operation when the switches (125, 126) are set to a character length erase operation and at the end of a word erase operation when the switches (125, 126) are set to a word length erase operation. 3. Typewriter according to dependent claim 2, characterized in that the termination circuit (73) has a third detection circuit (77) for detecting the completeness of a line erase operation, and that the blocking circuit (79) the further operation of the repetition circuit (75) at the end a line erase operation when the switches (125, 126) are set to a line length erase operation. 4. Typewriter according to the claim, characterized in that an operating part (190) and an associated circuit (80) for initiating a rewrite operation are provided that the circuit (80) by the control device (42) as the identified byte (41) associated with the current printing position (13) is controlled, and a control circuit (74) for automatically controlling the printing sequence of the printing unit (10) to rewrite the character determined by said byte (41) and to advance the printing position of the printing unit .