SU734801A1 - Device for recording information into magnetic disk-based storages - Google Patents

Description

This invention relates to storage media in which a recording medium is moved relative to a converter.

A device for recording information in magnetic disk drives is known in which, in the presence of defects in magnetic storage medium on a magnetic disk (LLM), the entire track on which defects 1 are detected is rejected.

However, the rejection of a full track in the presence of a defect on only a part of it is excessively coarse: in general, the defect takes only a small portion of the track, the rest of the track is fully functional, can be used to write / read data, but rejects together with the defective part of the carrier. As a result, the efficiency of the use of NMD is reduced due to the artificially created reduction in the effective capacity of packages of magnetic disks. The partitioning of all MD tracks into discrete zones (records) allows one to accurately and unambiguously localize the portion of the MD track on which there is a defect in the magnetic carrier by proper identification of records that appear during reading

failures due to defects in magnetic media, and not due to improper operation of hardware. Obviously, when identifying records belonging to defective parts of an MD package, the rest of the corresponding MD tracks can be used without any restrictions. The detection of zones belonging to the defective areas can be done by writing to the NMD of any data and their subsequent control reading. If there is no comparison on the checksum (if it is not caused by hardware failures), a sign indicating its defectiveness may be entered in the service part of the corresponding record in this case.

The closest in technical essence to the invention is a device for recording information in the NMD, containing a block for selecting a cylinder and a track, connected at the input to the first output of the control word register, and at the output to

20 to the first input of the recording unit, to the first and second inputs of the ring register control unit, to the first input of the checksum generation unit, the output of which is connected to the first inputs of the OR elements

the first group, the block forming the address marker, the output of which is connected to the second input of the recording unit, the output of which is connected to the third input of the control unit ring register, the buffer register connected to the outputs of the elements OR first | groups, and the outputs - with the second input of the checksum generation unit and with the inputs of the AND elements of the first group, the second group of OR logic elements connected to the inputs of the outputs of the AND elements of the first group and the output to the third input of the recording unit, a pulse generator connected on the output to the fourth input of the recording unit, the first counter connected to the output to the first input of the first decoder, the second input of which is connected to the second output of the control register, its words, the recording unit of the service gap and the source signal 2 the initial installation.  However, this device, ensuring the application of variable length records to the NMD track, requires a by-by-by-one sampling of information and computer memory, which necessitates repeated access to the memory.  In this case, the known device organizes the application of records with a format that does not allow the possibility of rejecting individual records in the presence of defects in the magnetic carrier, and prescribes the rejection of the entire track as a whole.  In addition, if this device is used to record and test readings in a working multiprogrammed mode of a computing system, the cost of the expensive memory and the need to repeatedly access it are obvious, which leads to a decrease in the efficiency of the computing system and also reduces the reliability of the device.  The purpose of the invention is to increase the reliability of the device.  The goal is achieved by the fact that the device contains the elements AND and OR, the second, third and fourth groups of elements AND, triggers, the second decoder, the first and second groups of keys, the second counter, the input of which is connected to the output of the first element AND, the first input of the first element OR and the third input of the checksum generation unit, the output of the second counter is connected to the first input of elements AND of the second group and to the first input of the second decoder, the second input of which is connected to the second input of the register (control word, and The second decoder is connected to the fourth input of the checksum generation unit, the first input of the first element I is connected to the first output of the first decipher, and the second input of the first element I is connected to the first inputs of the second and third elements And, one of the outputs of the ring register, the second inputs of the second and the third elements And connected to the second and third outputs of the first decoder, and the third inputs of the second and third elements And connected respectively with the first and second outputs of the first trigger, the outputs of the second and third second AND gates respectively connected to first and second inputs of second OR, kotorogb output connected to a first input of the fourth AND gate, a second input coupled to per-.  output of the second trigger, and the output of the fourth element I is connected to the first INPUT of the third trigger, the second input of which is connected to the output of the third OR element, the output of the third trigger is connected to the first inputs of the address marker generation unit and the fifth AND element whose output is connected to the first inputs the fourth OR element and the fourth trigger, the second input of which is connected to the output of the fifth OR element, the first output of the fourth trigger is connected to the first inputs of the sixth and seventh AND elements, and the second output the fourth the first trigger is connected to the first input of the eighth element AND, the output of which is connected to the first input of the first counter, the second input of which is connected to the output of the fourth element OR, the second input of which is connected. with the release of the first. the OR element and the first input of the second trigger, the second input of which is connected to the output of the seventh element AND, and the second output of the second trigger is connected to the second inputs of the AND elements of the first group and the first input of the ninth element And, the output of the sixth element And is connected to the first inputs of the first trigger and the third element OR, the second input of the ninth element AND is connected to the first output of the fifth trigger, the second output of which is connected to the first inputs of the tenth and eleventh.  And elements, the second inputs of which are connected to the first output of the service gap recording unit, the second output of which is from: connected to the first inputs of the sixth element OR, the twelfth, thirteenth element AND, and the fifth input of the recording block, the third input of the tenth element AND is connected to the first output of the sixth trigger, the second input of the twelfth element And and the first INPUT of the fourteenth element And, the second input of which is connected to the output of the fifteenth element And, and with the input of the service interval recording unit, the output of the thirteenth element And Connected to the first input of the fifth element OR, the output of the fourteenth element AND is connected to the first input of the fifth trigger, the second input of which is connected to the output of the first element OR, the output of the sixth element OR is connected to the first input of the seventh trigger, the output of which is connected to the first input of the fifteenth element AND, the output of the ninth element AND is connected to the second inputs of the elements AND of the second group and to the first input of the seventh element OR, the second input of which is connected to the first input of the sixth trigger and the output of the sixteenth element AND, out the seventh logical element OR is connected to the second input of the seventh trigger, the second output of the sixth trigger is connected to the third input of the eleventh element AND, the second input of the thirteenth element And, and the first input of the seventeenth element AND, the output of which is connected to the first input of the eighth element OR, whose output connected to the first input of the eighth trigger, the second input of which is connected to the output of the twelfth element And, the output of the eighth trigger is connected to the first input of the sixteenth element And, the output of the tenth element And with Connected to the first inputs of elements AND of the third group, the second inputs of which are connected to the outputs of the keys of the first group, and the outputs of elements AND of the third group are connected to the second inputs of the elements OR of the first group, the output of the eleventh element And connected to the first inputs of the elements of the fourth group, the second inputs which are connected to the outputs of the keys of the second group, and the outputs of the elements AND of the fourth group are connected to the third inputs of the elements OR of the first group, the fourth inputs of which are connected to the outputs of the elements AND of the second group, the third inputs of which are connected to the third output of the control word register, second inputs of the fifth, sixth, seventh, eighth, fifteenth, sixteenth and seventeenth elements And, fourth inputs of the tenth and eleventh elements And, the third inputs of the ninth and thirteenth elements And connected with the outputs of the ring register, the second inputs of the first, third, fifth, sixth, eighth elements of OR, the first and sixth triggers are connected to the signal source of the initial installation.  FIG.  1 shows the format of the record, which the proposed device puts on the IDB track; in fig.  2 shows a functional diagram of the device; in fig.  3 - time diagram of the device.  Record 1 is placed on the MD track (see  FIG.  1, for example, two tracks are shown), each of which includes a service space 2, an address marker 3, a record identifier 4, a service space 5, a service word 6 characterizing the fault of the track section that contains the data field 7, the service space 8 , checksum 9 and track index 10.  Device (see  FIG.  2) contains from the first to the seventeenth element 11-27 And, block 28 records of the service gap, the first 29 and second 30 counters, the first to the eighth elements 31-38 OR, the first 39 and second 40 decoders, the first to the eighth triggers 41- 48, the first 49 and the second 50 groups of elements OR, from the first to the fourth groups of elements 51-54 AND, the first 55 and.  second key group 56, cylinder and track selection unit 57, pulse generator 58, for example quartz, formation block 60, ring register control block 61, control word register 62, ring register 63, buffer register 64, checksum block 65.  The input unit 57 is connected to the first output of the register 62, and the output to the first input of the block 60, to the first and second inputs of the block 61, to the first input of the block 65, the output of which is connected to the first inputs of the elements 31 OR.  The output of block 59 is connected to the second input of block 60, the output of which is connected to the third input of block 61.  The outputs of the register 64 are connected to the second input of the block 65.  The third and fourth inputs of the block 60 are connected respectively to the outputs of the elements 50 OR and the pulse generator 58.  The first and second inputs of the first decoder 39. connected to the output of the counter 30 and the second output of the register 62.  The input of the counter 30 is connected to the output of the first element 11 I, the first input of the first element 31 OR and the third input of the checksum generation unit 65, the output of the second counter AOR is connected to the first inputs of the elements 52 I and to the first input of the second decoder 40, the second input of which is connected to the second output of the control word register 62, and the output of the second decoder 40 is connected to the control unit four of the control unit t. .  f Noah 65, the first input of the first element 11 And is connected to the first output of the first decoder 39, and the second input of the first element 11 And is connected to the first inputs of the second and third elements 12 and 13.  And, as well as with one of the outputs of the ring register 63, the second inputs of the second and third elements 12 and 13 And are connected to the second and third outputs of the first decoder 39, and their third inputs are connected respectively to the first and second inputs of the first trigger 41, the outputs of the second and The third elements 12 and 13 And are connected respectively to the first and second inputs of the second element 32 OR, the output of which is connected to the first input of the fourth element 14 And, the second input of which is connected to the first output of the second trigger 42, and the output of the fourth element 14 And Inen with the first input of the third flip-flop 43, the second input of which is connected to the output of the third element 33 OR, the output of the third flip-flop 43 is connected to the first inputs of the block forming the address marker 59 and the fifth element 15 AND whose output is connected to the first inputs of the fourth element 34 OR the fourth trigger 44, the second of which is connected to the output of the fifth element 35 OR, the first output of the fourth trigger 44 is connected to the first inputs of the sixth and seventh elements 16 and 17, and the second output of the fourth trigger 47 is connected to the first input of the The second element 18 AND, the output of which is connected to the first input of the first counter 29, the second vhbD which is connected to the output of the fourth element 34 OR, the second input of which ---- roto is connected to the output of the first element 31 OR and the first input of the second trigger 42, the second the input of which is connected to the - OUTPUT of the seventh element 17 And, and the second output of the second trigger 42 is connected to the second one of the inputs of the elements 51 And the first input of the ninth element 19 And, the output of the sixth element 16 And is connected to the first inputs of the first trigger 41 and the third element 33 OR, the second in the stroke of the ninth element 19 And is connected to the first input of the fifth trigger 45, the second output of which is connected to the first inputs of the tenth 20 and eleventh 11 elements And, the second inputs of which are connected to the first output of the service interval recording unit 28, the second output of which is connected to the first the inputs of the sixth element OR 36, the twelfth 22, the thirteenth 23 elements AND and the fifth input of the recording block 60, the third input of the tenth element 20 AND connected to the first output of the sixth trigger 46, the second input of the twelfth element 22 AND, and the first input fourteen About element 24 AND, the second input is connected to the output of element 25 AND and to the input of the service space entry block 28, the output of the thirteenth element 23 AND is connected to the first input of the fifth element 35 OR, the output of the fourteenth element 24 AND is connected to the first input of the fifth trigger 45, the second input of which is connected to the output of the first element 31 OR, the output of the sixth element 36 OR is connected to the first input of the seventh trigger 47, the output of which is connected to i by the first input of element 25 AND, the output of the ninth element 19 AND is connected to the second inputs of elements 52 And and with The first input of the seventh element 37 OR, the second input of which is connected to the first input of the sixth trigger 46, and the output of the element 26 AND, the output of the seventh element 37 OR is connected to the second input of the seventh trigger 47, the second output of the sixth trigger 46, is connected to the third input of the eleventh element 21 And, with the second input of the thirteenth element 23 And with the first input of the element 27 I.  the output of which is connected to the first input of the eighth element 38 OR, the output of which is Schecinjon to the first input of the eighth trigger 48, the second input of which is connected to the output of the twelfth element 22 And, the output of the eighth trigger 48 is connected to the first input of element 26 And, the output of the tenth element 20 And connected to the first inputs of elements 53 AND, the secondary inputs of which are connected to the output of keys 55, and the outputs of elements 53 AND connected to the second inputs of elements 49 OR, the output of the eleventh element 21 AND connected to the first inputs of elements 54 AND, the second inputs of which the dinene with the outputs of the keys 56, and the outputs of the elements 54 I connected to the third inputs of the elements 49 OR, the fourth inputs of which are connected to the inputs of the elements 52 AND, the third inputs of which are connected to the third output of the control word register 62, the second inputs of the elements 15-18 And 25-27, the fourth inputs of the tenth of the 20th and the eleventh 21 And elements, the third inputs of the nineteenth and thirteenth 23 And elements connected to the outputs of the ring register 63, the second inputs of the elements 31, 33, 35, 36 and 38 OR triggers 41 and 46 are connected with the initial signal source (in FIG.  2 not shown).  Two successive recordings are recorded on the magnetic disk track.  Through the computer channel (in FIG.  2 is not shown) control information is fed into the device, which is entered into register 62.  The control word contains information from the applied record, namely the cylinder number, the track number on the cylinder, the length of one record, the total number of records on the track.  When entering run. the signal to the input of block 36, the latter allows the operation of register 63, which generates a sequence of clock pulses (TI), associated with bits of transmitted control words.  . In this case, each given TI sequence (except the first one) is shifted according to the preceding TI sequence by the duration of the TI itself.  The number of sequences TI corresponds to the size of the machine word.  So, if the machine word has 24 bits, then the DIT ring register generates 25 TI series: 1TI, (ITT IC T T 2TI,. . . 24TI and 25 TI, where 25TI is the TI service sequence.  The clock pulses are fed to the input of block 57, as a result of which block 57 generates control signals for positioning the CID head block.  When a signal is received from the TLM, the Attention output of the block 57 goes to one of the inputs of the control unit of the ring register 61, which prohibits the operation of the ring register 63 until the index of the TLI is received at one of the inputs 57 of the cylinder and track selection.  After that, a signal is taken from one of the outputs of block 57, which sets the recording mode in the data recording block 60, turns on the ring recorder, the histor 63 via the ring register control block 61 and switches the checksum block 65 to the recording mode.  At the output of the 63 annular perHctpa block, there appear sequences of clock pulses.  Next, on the LDPE track, a recording is formed and applied (the recording format is shown in FIG.  one).  Service interval 2 contains two zero words in which the clock pulses and zero information are recorded.  The formation of the correction record service gap 2 is as follows.  When a pulse register 23 of TI 23 appears at the input of the ring register 63, it arrives at one of the inputs of element 18 AND, which is allowed by the other input.  The output signal of the element 18 And (see  FIG.  3, pos.  a) arrives at the counting input of the counter 29.  Each TI from the sequence of 23TI means that one machine passes to the record, for example, a 24-bit word.  At this moment, the write information from the buffer register 64 does not pass to the data recording unit 60, since the 51 I elements are prohibited from one input.  In connection with this, zero words enter the head of the read / write NMD, t.  e.  only sync pulses received from the generator 58 are transmitted to the recording (logical “O” recordings occur).  Counter 29 counts zero words and after two such words on decoder 39 a signal arrives at one of the inputs of element 12 I, which is enabled via the other input, and the third gate is gated with a pulse from the 25TI sequence.  On the 25th TI, at the output of element 12 I, an output signal appears (see  FIG.  3, pos.  b), which through the element 3,2 OR goes to one of the inputs of the element 14 And, which is permitted by another input connected to the zero output of the trigger 42.  At this point, the recording of service gap 2 ends and the formation and recording of the address marker 3 on the NMD track begins.  Address marker 3 contains a special code combination that is not repeated anywhere else in other service and information words.  This combination presupposes a sequence of sync and logical "1", the absence of sync pulses and the presence of logical "1, lack of data (logical" O) and the presence of sync pulses.  Formation and recording of the address marker is as follows.  The signal from the output of the element 14 and goes to one of the inputs of the trigger 43 and translates it into a single state (see  FIG.  3, pos.  at).  As a result, it is activated by one of the inputs of the block forming the address marker 59.  At the same time resolves element 15 I.  From this moment on, the address marker, which is removed from the output of the formation unit of the address marker 59, is recorded on the IDD track.  When the TI from the 1 TI sequence arrives at the other input of element 15, which corresponds to the beginning of the third word, the output of element 15 will result in a signal which, through element 34 OR, sets the counter 29 words to the initial (zero) state (see  FIG.  3, pos.  d), and the trigger 44 translates into a single state, as a result, elements 16 and 17 AND are allowed for one input (see  FIG.  3, pos.  d).  With the arrival of TI from the sequence 17TI, a signal appears at the output of the element I 16 at its output (see  FIG.  3, pos.  e), which sets the trigger 41 to a single state (see  FIG.  3, pos.  h), and, through element 33, it triggers trigger 43 to the zero state.  Thus, the trigger 43 generates a signal controlling the operation of the block 59 of the formation of the address marker.  At the end of the recording of the address marker on one of the inputs of element 17 I, which is permitted via the other input, a TI from the 25Т sequence appears, as a result of which, a signal appears at the input of this element (see  FIG.  3, pos.  g) setting the trigger 42 to a single state (see  FIG.  3, pos.  and), which indicates that the recording of the address marker for this record is completed.  From this point on, the formation and recording of a record ID identifier to the NMD track begins.  The identifier of the record is the word in which the physical address of the entry is encoded, t.  e.  cylinder number, recording head number (NMD read, track record number, recording length).  The formation and recording of record identifier 4 is as follows.  When the flip-flop 42 goes to the unit state of the element 51 And is resolved on one of the inputs.  As a result, information is transferred from the buffer register block 64 via elements 51 AND, 50 OR, block 60 of writing data to the read / write block of the non-profit bank code.  Along with this, element 19 And on one of the inputs connected to the single output of flip-flop 42, is permitted, on the other input connected to the zero output of flip-flop 45, element 19 is also allowed.  Therefore, with the arrival at its third input, TI from the 1TI sequence, at the output of element 19, a signal appears (see  FIG.  3, pos.  k), which arrives at one of the inputs of elements 52 I, resolving the latter.  The other inputs of elements 52 I receive information from block 62 of the control word register, indicating the cylinder and track number, length, records, as well as information from counter 30, indicating the sequence number of the record on the track.  As a result, the record indicator 4 is formed in elements 52 I, which is then entered through the elements 49 OR in block 64 of the buffer register for a paragliding-sequential transformation.  Upon receipt of the TI series and: TI - 24TI sequences to the input of elements 51 And it is resolved via other inputs and. record identifier 4, converted to a sequential code, through the elements 50 - passes to the entry in the NMD.  At the same time, the signal from the output of elements 19 And through the ale. .  -. Step 37 OR enters one of the inputs of the trigger 47 and translates it into a single state (see  FIG.  3, pos.  l).  The signal from the single output of the trigger 47 is fed to one of the inputs of the element 25 I, which is gated at the other input by a TI of the 24T string.  The output signal of the element 35 And (see  FIG.  3, pos.  m) corresponds to the end of the record ID 4.  This output signal goes to one of the inputs. , element 24 And, which. on the other entrance is allowed. .  At the same time output sig.  cash  element 24 and. translates trigger 45 into a single state (see  FIG.  3, pos.  four), .  prohibition element 19. And on the input connected to the zero output of the trigger 45, and allowing on the inputs connected to the single output, the trigger 45, the elements 20 and 21 I.  In addition, the output of element 25 I is. input signal for block 28 recording service gap.  This completes the formation of the record id 4 and the device proceeds. to the formation and recording of the first service gap 5.  . g.  Service interval 5 (sync word) contains zero information in all bits except for the last two bits (23rd and 24th bits), in which the logical “1.  The formation and recording of the first service gap 5 takes place as follows.  .  The signal from the output of the element 25 And enters the input of the block 28 recording service gap and initiates its work.  In this case, in block 64 of the buffer register, null information is contained, since elements 19-21 And therefore the elements 52-54 AND are prohibited.  The output signal appearing on one of the outputs of block 28 for recording the service gap (see  FIG.  3, pos.  n) arrives at one of the inputs of the data recording unit 60, which leads to recording on the track GWD of the service gap 5 (sync word).  In addition, this output signal through the element 36 OR triggers the trigger 47 into the zero state, and also goes to one of the input elements 22 and 23 AND, allowing the last of the rfb wth penetration through these inputs.  Element 22 And allowed on another input connected to the zero output of the trigger 46, in rezula-athe what at the output of the element. 22 And a signal appears that sets the trigger 48 to one state.  This moment corresponds to the end of the recording of the first service gap 5 on the NMD track and the beginning of the recording of the control word 6.  Service word 6 in the first three bits contains code information about the state of the magnetic media section on which data field 7 is located (the code is "good or bad".  In the subsequent bits of the word, 6, there are sync pulses and zero data if the magnetic carrier has no defects in the area of data field 7 and in the first three bits of the word 6, the code is "good.  If the magnetic medium in the specified area of the ow etc is defective and in the first three bits of this word the code “is faulty”, then in the subsequent bits of the word 6 a new record indicator providing readdressing is recorded to the spare track to which the record was transferred, said on the defective magnetic media.  The formation and recording of the service word 6 is as follows.  After the recording of the first service gap 5 is completed, the element 20 And with the arrival of the TI from the sequence 1-TI is resolved through all four inputs and a signal appears at its end (see  FIG.  3, pos.  with), . The element 53, which permits one of the inputs, to the other inputs of which the information of the service word 6 is supplied.  This information in the form of the corresponding code is pre-dialed by the operator on the keys 55. and from their outputs they are fed to the inputs of elements 53 I.  In this case, it is initially assumed that the surface of the magnetic carrier is free of defects and, based on this assumption, the operator dials on the keys 55 the code corresponding to the health or absence of defects in the magnetic carrier on the given track.  From the outputs of the elements 53 AND office spruce 6 through the elements 49 OR is transferred to the buffer register 64 and after parallel-serial conversion on the elements 51 and 49 AND, 50 OR through the block 60 records data enters the head write / read NMD.  During this conversion, element 26 AND on one of the inputs connected to the single output of trigger 48 is resolved, therefore with the arrival on the other input of element 26 AND TI from the 4TI sequence, a signal appears on the output of this element, triggering 47 through element 37 OR a single state, wherein the trigger 46 sets on one of the inputs to the single state directly (see  FIG.  3, pos.  about).  As a result, the element 25 And the input connected to the single output of the trigger 47 is again allowed, the elements 20, 24 and 22 And the inputs connected to the zero output of the trigger 46 are prohibited, and the elements 21, 27 and 23 And the inputs connected to the single output of the trigger 46, are allowed.  This state is preserved until the end of the recording of the service word 6 on the IDD track.  After this, the second service gap 5 is formed and recorded.  At the end of the recording of the service word 6, one of the inputs of element 25 I enters the TI from the 24TI sequence and at its output a signal appears, for the second time. start up st block 28 record service gap.  The signal from one of the outputs of block 28 (see  FIG.  3, pos.  p) prohibits the elements 20 and 21 and the corresponding inputs.  As a result, with the arrival at the other input of the element 21 AND TI from the 1TI sequence, the signal does not appear at its output.  At the same time, block 18.  service pro- recordings, the interput generates an output signal (see  FIG.  3, pos.  p), which is fed to one of the inputs of the data record block 60, element 23 I, and also through element 36 OR sets the trigger 47 to the zero state, as a result of which element 25 I is inhibited according to one of the inputs.  Upon completion of the writing of the code of the service word 5 on the track, the IDT element 23 And is allowed by two inputs and with the arrival at its third input TI from the 24TI sequence at the output of element 23 AND a signal appears (see  FIG.  3, pos. y), which, via element 35 OR, sets the trigger 44 to the zero state, with the result that element 18 And by one of the inputs is allowed, and elements 16 and 17 And by one of the inputs are prohibited.  At this time, the formation and recording of the second service gap 5 is completed, and the yStroictvo proceeds to the recording of the data field 7.  The data field 7 records a sequence of words, the information content of which is determined by the state of the keys 56.  Field 7 of the data of all records on a given track, GID has the same length.  However, on different tracks the length of the data field may be different.  After recording the second service gap 5, element 21 I is allowed by three inputs and when its fourth input arrives pulses of the 1TI sequence, an output of element 21 I appears each time (see  FIG.  3, pos.  r), which allows the elements 54 And one of the inputs.  The other inputs of the elements 54 And receives the code sequence, dialed using the keys 56 |.  Information From the output of the elements 54 AND through the elements 49 OR enters the input of the buffer register 64 for,; parallel-serial conversion and recording of information through the recording unit 60 on the NMD track in the data field 7.  When the first word is recorded in the data field 7, one of the inputs of element 18 AND, allowed by the other input, receives a TI from the sequence 23TI, and as a result, the output of element 18 AND a signal appears at the counting input of counter 29.  Subsequently, after the end of the recording, in the field 7 of the data of each word at the output of the element 18, the signal arriving at the counting input of the counter 29 appears.  This ensures the counting of the number of words recorded in the data field 7.  Descrambler 38 is configured for a given length of field 7 data (for the number of words to be recorded in data field 7).  Information about the length of the data field 7 (about the number of words in it) goes to the decoder 39 from the control word register 62 to its other input.  Depending on the specified length of the data field 7, a signal appears at the same output of the decoder 39 indicating that the last word of the data field 7 has been recorded.  This signal goes to one of.  input element And 55.  With the arrival of his other vkhd TI from a sequence of 25TI on.  Element 11 output And a signal appears (see  FIG.  3, pos.  f) arriving at one of the inputs of the OR element 31 and the checksum forming unit 65.  The same output signal is fed to the input of the counter 30 as a counting pulse.  The signal from the output of element 31 OR is fed to one of the inputs of trigger 42 and puts it in the zero state.  The same signal, besides, through the element 34 OR transfers the counter 29 to the zero state.  As a result, the AND element 14 is permitted by one of the inputs, and the AND element 19 and the AND elements 51 by one of the inputs connected to the single output of the flip-flop 42 are prohibited.  Such a device state means that the recording of the data field 7 is completed, after which the device proceeds to write the checksum 9.  . The checksum is a word equal to the cyclic sum of all the words in the data field 7.  When writing the words data field 7 to the NMD track, words from the buffer register 64 constantly do the same to one of the inputs of the checksum generation unit 65, where, according to the clock pulses, the checksum of the data field 7 of the data field 7 is formed.  At the end of the recording, field 7 of data at the output of element 11 And a signal appears.  arriving at one of the inputs of the block 65 forming the checksum 6.  By this signal, the checksum through the OR elements 49 is rewritten into the buffer register 64, from which, after a parallel-serial conversion through the elements 5 G AND, the elements 50 OR, the write block 60 enters in a serial code into the read-write block of the CID.  Thereafter, the formation and recording of the service gap 8 is performed.  At the end of the recording, the device analyzes whether the NMD of the checksum is 9, whether it is necessary to apply the second, third, etc.  records  The analysis is performed as follows.  The information in the number of written records is contained in the counter 30, and the data on the number of records to be applied is contained in the control word entered into the control word register 62 from the computer channel.  The decoder 40 generates an output signal depending on the state of the counter 30 and the state of the bits of the control word register 62, in which INPUT data on the number of records to be applied to the NMD track.  When the state of the counter 30 corresponds to the number of records that need to be applied to the track, a signal appears at the output of the decoder 40 indicating that the entire specified number of records has been applied to the track.  In this embodiment, the device considers drawing two records on the LDPE track, so after recording the checksum 9, the device proceeds to the formation of the service gap 8 and the next (second) record.  The length of the service gap 8 is variable, it is directly proportional to the length of the data field 7.  Information about the length of the data field 7 comes from one of the outputs of the register, 62 control words to one of the inputs of the decoder / 39.  Service interval 8 contains a sequence of words in which zero information is recorded (presence of clock pulses, lack of data).  After writing the checksum 9, clock pulses from the sequence 23RT continue to arrive at one of the inputs of element 18 And allowed through the other input, as a result, the output of element 18 And signals appear that are counted by the counter 29 of the zero state in which the counter is transferred upon completion of the recording of data field 7.  At this time, the buffer register 64 contains zero information (the trigger 42 is in the zero state), the address marker generation unit 59 and the service interval recording block 28 do not generate output signals, therefore zero information passes to the NMD.  Since decipher 39 is set to a certain length of service gap 8, when counter 29 reaches a state corresponding to a given length of service gap 8, a signal appears on one of the outputs of the decoder 39 indicating that the required number of zero words of the service gap is written on the NMD track eight.  This signal is sent to one of the inputs of element 13 I, which is allowed by another input connected to the single output of the trigger 41, and with the arrival at the third input of element 13 and the clock pulse from the 25TI sequence, a signal appears at its output  FIG.  3, pos.  t), which through element 32 OR resolves one of the inputs of element 14 AND, the other input of which is also allowed, since it is connected to the zero output of the trigger 42, which at this moment is in the zero state.  The signal from the output of the element 14 And enters the single output of the trigger 43 and translates it into a single state.  As a result, one of the inputs resolves the element 15 OR, and the operation of the block 59 of the formation of the address marker is initiated.  With the arrival of TI from the sequence 1 TI, at the output of element 15, a signal appears which, through element 34 OR sets counter 29 to the zero state.  From this moment on, the device starts recording the address marker 3 of the next (second) record and the device operation cycle repeats.  At the end of the application of the second record data to the NMD field 7 (in this case, this record is the last one on the track), a signal appears at the output of the decoder 40 indicating that the recording of the NMD track has ended.  This signal from the output of the decoder 40 is fed to one of the inputs of the checksum generation unit 65.  When the checksum 9 of the second (and last) recording is recorded on the NMD track, block 65 generates a signal indicating that all the recordings on this track are plotted.  In the future, this signal can be used as a signal notifying the computer that all operations associated with one control word transferred from the computer memory to the device have been completely completed, all recordings on this LWM track are completed and executed selection of the next control word from the computer memory containing the description of the records of a different NMD track for transferring it through the computer channel to the control word register 62 to continue recordings.  Entries marked on the IDB track are checked by checksum.  The incomparability of the checksum as a result of re-reading any record suggests that in the section of the NMD track, on which there is a data field 7 of the corresponding record, the magnetic media is defective.  In this case, instead of the service word b of this record, which is initially recorded with the sign "correctly," the service word is applied, for example, through the computer channel with the sign "fault in the first three bits and with additional information about the spare track to which the record is transferred .  Subsequently, when using a package of magnetic disks in computing systems, if this record is accessed on the main track, in the data field of which the magnetic media is defective, such a record is read and an automatic redirection to the spare track is arranged, the reduction of which is already contained in the service word 6 .

The control device for recording information in the NMD requires, when applying all records to any track of the NMD, only a single access to the computer memory in order to select a control word containing a description of the records on the corresponding track, the formation of records is performed in the device itself; characterized in connection with this high degree of autonomy, which is maintained, in particular by the fact that it contains two groups of keys for an autonomous set of codes corresponding to the feature "operability 7 data; allows, by using keys for autonomous dialing of code, over a wide range, to vary the structure of the words recorded in field 7 of data, and thereby effectively check the state of the sections of magnetic media on which data fields 7 are located; allows you to eliminate the time costs associated with the organization of the redirection to the alternate track at the time of the task, -T. that is, in the process of applying directly the work records used to implement the computational process; allows to fully utilize all the useful volume of magnetic disk packets due to the detection of records located on defective areas of magnetic media.

Claims (2)

Invention Formula A device for recording information in magnetic disk drives, comprising a cylinder and track selection unit, connected at the input to the first output of the control word register, and at the output to the first input of the recording unit, to the first and second inputs of the control ring-register, to the first to the input of the checksum generation unit, the output of which is connected to the first inputs of the elements OR of the first group, the block of formation of the address marker, the output of which is connected to the second input of the recording unit, the output of which is connected to the third input du ring control unit register, a buffer register connected at the input with the outputs of the elements OR of the first group, and at the outputs with the second input of the checksum generation unit and with the inputs of the AND elements of the first group, the second group of OR logic elements connected by the inputs with the outputs of the AND elements of the first group and at the output with the third input of the recording unit, a pulse generator connected to the output of the fourth input of the recording unit, the first counter connected to the output of the first input of the first descriptor, the second input of which is connected to the second output of the register of the service space, the source of the initial installation signal, characterized in that, in order to increase the reliability of the device, it contains elements AND and OR, second, third and fourth groups of elements AND, triggers, second decipher, first and second groups keys, the second counter, the input of which is connected to J output of the first element AND, the first input of the first OR element and the third input of the checksum generation unit, the output of the second counter is connected to the first input of the AND elements of the second group and the first input of the second decipher, the second input of which is connected to the second output of the control word register, and the output of the second descrambler is connected to the fourth input of the checksum generation unit, the first input of the first element I is connected to the first output of the first descrambler, and the second input of the first element I is connected to the first inputs The signals of the second and third elements And, with one of the outputs of the ring register, the second inputs of the second and third elements And are connected to the second and third outputs of the first decoder, and the third inputs of the second and third elements And are connected respectively to the first and second outputs of the first trigger, outputs second and third - elements And are connected respectively to the first and second inputs of the second element OR, the output of which is connected to the first input of the fourth element And, the second input of which is connected to the first output of the second trigger, and the output of the fourth element And connected to the first input of the third trigger, the second input of which connected to the output of the third element OR, the output of the third trigger is connected to the first inputs of the block forming the address marker and the fifth element AND, the output of which is connected to the first inputs of the fourth element OR and the fourth the first trigger whose second input is connected to the output of the fifth OR element, the first output of the fourth 19 of the trigger is connected to the first inputs of the sixth and seventh And elements, and the second fourth trigger is connected by the first input of the eighth And element, the output of which is connected to the first input of the first counter, the second input of which is connected to the output of the fourth element OR, the second input of which is connected to the output of the first element With the first BXolOMfffoporo trigger, the second input of which is connected to the output of the seventh element And, and the second output of the second trigger is connected to the second inputs of the elements And of the first group and the first input of the ninth element And, you the stroke of the sixth element And is connected to the first inputs of the first trigger and the third element OR, the second input of the ninth element And is connected to the first output of the fifth trigger, the second output of which is connected to the first inputs of the tenth and eleventh And elements, the second inputs of which are connected to the first output of the block recording the service gap, the second output of which is connected to the first inputs of the sixth element OR, the twelfth, thirteenth AND elements and the fifth input of the recording unit, the third Input of the tenth element AND is connected to the first output of the sixth the second trigger, the second input of the twelfth element AND and the first input of the fourteenth element And, the second input of which is connected to the output of the fifteenth element AND and to the input of the service interval recording unit, the output of thirteen element AND is connected to the nepBibiM input of the fifth element OR, the output of the fourteenth element AND connected to the first input of the fifth trigger, the second input of which is connected to the output of the first OR element, the output of the sixth OR element is connected to the first input of the seventh trigger, the output of which is connected to the first input of the fifteenth of gate AND, v1hod ninth AND gate is coupled to second inputs of AND gates of the second group and the first input of the seventh OR gate, a second input coupled to the first input of the sixth flip-flop and the output of AND XVI, yield seventh 734801 20 logical element OR is connected to the second input of the seventh trigger, the second output of the sixth trigger is connected to the third input of the eleventh element AND, to the second input of the thirteenth element and to the first input of the seventeenth element AND whose output is connected to the first input of the eighth element OR, the output of which is connected with the first input of the eighth trigger, the second input of which is connected to the output of the twelfth element And, the output of the eighth trigger is connected to the first input of the sixteenth element And, the output of the tenth element And connected to the first the primary inputs of the elements And the third group, the second inputs of which are connected to the outputs of the keys of the first group, and. the outputs of elements AND of the third group are connected to the second inputs of the elements OR of the first group, the output of the eleventh element AND is connected to the first inputs of the elements AND of the fourth group, the second inputs of which are connected to the outputs of the keys of the second group, and the outputs of the elements AND of the fourth group are connected to the third inputs of the elements OR the first groups, the fourth inputs of which are connected to the outputs of elements AND of the second group, the third inputs of which are connected to the third output of the control register; its words, the second inputs of the fifth, sixth, seventh, eighth , the fifteenth, sixteenth and seventeenth elements AND, the fourth inputs of the tenth and eleventh elements AND, the third inputs of the ninth and thirteenth elements AND are connected to the outputs of the LS register, the second inputs of the first, third, fifth, sixth, eighth elements OR, the first and The sixth flip-flops are connected to the source signal of the initial installation. Sources of information taken into account during the examination 1. The IBM-3bd system. Introduction to direct access storage and data organization methods. M., 4Statistics, 1974.1 p. 33.V- ;, 2. US patent number 3312948, cl. 340-172.5, 1967 (prototype). about 0 BUT. . . Tz § GU E N "one os 41 five to P  i / .. i   ,,   "Aii