| 摘要 |
<p>1,175,172. Dynamic magnetic data stores; local circuits. INTERNATIONAL BUSINESS MACHINES CORP. 25 Jan., 1968 [22 March, 1967], No. 3870/68. Headings G4C and G5R. [Also in Division H3] In binary data-recording systems where the information 14 (Fig. 1) is stored as major magnetic transitions, i.e. abrupt changes in the intensity of magnetization 14a, 14b, in a magnetic medium (disc, tape or drum), in order to prevent shifting of the peaks 16a, 16b, on read-out 16, each major transition is followed by a minor transition 18c, 18d (Fig. 2) of lesser magnitude, preferably 15-35%, and opposite polarity so that the read-out peaks 20a, 20b, are substantially symmetrical. The technique is suitable for phase modulation, NRZ and FM recording systems, particularly those which do not fully saturate the entire thickness of the magnetic coating. Two systems are described: Phase encoding (Fig. 4); Binary data A is mixed with clock pulses B in an EXCLUSIVE-OR circuit 46 to produce a phase-encoded signal C. Each positive or negative transition triggers a single shot 72 to open AND-gate 70 for one-sixth of the clock period, thereby adding at 66 a current I H from source 64 to a current I L from source 62 to produce the desired recording waveform as 18 (Fig. 2). The waveform, enabled at AND- gate 76, is fed to AND-gates 78, 80 which feed the information to respective ends of a centretapped write head 60 so as to magnetize tape 40 according to the coded information. The recording block 50 may be constituted by a transistor circuit (Fig. 6, not shown; see Division H3). The read-out information is amplified 90, differentiated 92 and limited 94 to produce a waveform G the same as the encoded information at C. This waveform is converted to binary notation by comparison in detector 102 with square wave pulses K derived from a variable frequency clock 96 generating a sawtooth waveform. The clock is synchronized with the output G by comparing the sawtooth in unit 106 with pulses generated in unit 104 whenever an output peak in G occurs. The correction circuits 108 may include a memory based on a trend-of-error to avoid correction based on noise or pulse-crowding effects. The write head 60 may be arranged to erase the tape 40 by connecting a second single-shot (142, Fig. 7, not shown) and inverter (144) between the input 48 and an OR-gate (146) connected between the single-shot 72 and AND- gate 70. The single-shot (142) has a delay or pulse duration longer than a bit interval so that it is energized at least once per interval and no output is supplied until information ceases, whereupon it opens AND-gate 70 to allow passage of I H + I L as erase current to the write head. NRZ encoding (Figs. 8, 9, not shown).-The system is identical to Fig. 4 except that the information to be recorded (W) is combined in an AND-gate (150) with pulses (X) and the output fed to a binary trigger (154) which supplies the recording circuit 50.</p> |
