Abstract: A method of manufacturing a magnetic tachometer used to generate a signal as a function of the velocity of a transducer positioning arm in a disk drive. The tachometer is formed over a one piece plastic insert having a first and second portion separated by a central breakaway region. An armature member is disposed over each of said first and second insert portion and a flexible connector is placed on a groove cut on a surface of said plastic insert. Two coils are simultaneously wound over said first and second insert portion, respectively, and connected to the flex connection. The insert is then bent to snap the breakaway region, and the resulting two coil subassemblies are folded and fastened to spacers to form a pair of fixed parallel coils. The separation between the coil is maintained at a predetermined value by the spacers to allow a magnet, attached to a counterbalance portion of a rotary positioning arm, to move therebetween and thus to generate a voltage as a function of the velocity of the magnet.
Abstract: The present invention provides translation circuitry, which in one mode of operation acts to encode variable length data words into fixed rate data coded words for use with a communication channel, or a recording means, such as a magnetic recording medium and which in another mode of operation acts to decode the coded words to data words. The translation circuitry functions such that in an encoding operation, the second and third bits of a three-bit coded word respectively have the same binary values as the first and second bits of the data word, which the coded word represents and the second and sixth bits of a six-bit coded word respectively have the same binary values as the third and fourth bits of the data word which the coded word represents.
Abstract: The present arrangement includes a circuit to receive non-differentiated pulse signals from the read circuitry of a magnetic recording medium system. These non-differentiated pulse signals are transmitted to a circuit which averages the values of the peaks of said signals, takes a predetermined percentage of that average value and produces a peak reference signal. The peak reference signal is transmitted to a comparison circuit whereat it is compared with the non-differentiated pulse signals and if the value of the peaks of the latter signals exceed the value of the peak reference signal, the comparison circuit will provide an output signal. The non-differentiated pulse signals are also transmitted to a differentiation circuit to effect a differentiation thereof and therefrom are transmitted to a zero crossover circuit. The zero crossover circuit provides a signal with a useful rising or falling edge, whose rising and falling edges occur at the zero crossovers of the differentiated signals.
Abstract: The present invention includes a first input signal circuit to receive pulse signals from a voltage-controlled oscillator (VCO), or some other controllable pulse signal source, and a second input signal circuit to receive pulse signals from a magnetic recording medium, or some pulse signal source, with which the voltage controlled oscillator is to be put in phase synchronization. A correction signal generator circuit is connected to both the input signal circuits to provide a first correction signal in response to a pulse signal from the recording medium and to provide a second correction signal in response to a pulse signal from the VCO. There is a third circuit which monitors how long a correction signal is in effect and if such a correction signal is present for longer than a predetermined time, the third circuit terminates the correction signal to enable a new correction signal to be generated in response to the next one of said input signals to arrive.