Abstract: A disk drive read circuit is disclosed comprising a read element for generating a read signal, and a sense amplifier comprising an input terminal coupled through a first capacitor to the read element and an output terminal coupled through a second capacitor to a transmission line, wherein the sense amplifier is for amplifying the read signal.

Abstract: A disk drive includes a write head that includes a slider, a write transducer disposed on the slider, and a laser device affixed to the slider. The write transducer is driven by a first electrical signal that is carried on at least one of a plurality of conductive traces of a laminated flexure to which the write head is attached. The laser device is driven by a second electrical signal that is also carried by the same at least one of the plurality of conductive traces. The first signal is characterized by a first frequency, and the second electrical signal is characterized by a second frequency that is different from the first frequency.

Abstract: A disk drive read circuit is disclosed comprising a read element for generating a read signal, and a sense amplifier comprising an input terminal coupled through a first capacitor to the read element and an output terminal coupled through a second capacitor to a transmission line, wherein the sense amplifier is for amplifying the read signal.

Abstract: A disk drive suspension assembly has a load beam and a laminated flexure attached to the load beam. The laminated flexure includes a structural layer with a head mounting tongue, and first and second conductive layers. A first dielectric layer is disposed between the structural layer and the first conductive layer, and a second dielectric layer is disposed between the first conductive layer and the second conductive layer. The first conductive layer includes a first plurality of interleaved traces with at least a first conductive trace and a second conductive trace separated by a first lateral intertrace spacing. The second conductive layer includes a second plurality of interleaved traces with at least a third conductive trace and a fourth conductive trace separated by a second lateral intertrace spacing. The fourth conductive trace overlies the first lateral intertrace spacing and the first conductive trace underlies the second lateral intertrace spacing.

Abstract: A disk drive is disclosed comprising a disk, an actuator arm comprising a suspension, and a head coupled to a distal end of the suspension, wherein the head comprises a write coil. The disk drive further comprises a preamp operable to generate a write current applied to the write coil in response to a single polarity supply voltage which may be positive or negative. In one embodiment, the transmission lines that couple the write coil to the suspension comprise respective, parallel plate sections that form a capacitance which enables driving the preamp with the single polarity supply voltage.

Abstract: A solderless compression connector is disclosed operable to couple first and second electrical components. The solderless compression connector comprises a housing comprising a dielectric forming a plurality of chambers, and an elongated conducting element disposed in each chamber. Each elongated conducting element comprises a first end operable to engage a first electrical lead of the first electrical component, and a second end operable to engage a second electrical lead of the second electrical component. Each elongated conducting element comprises a substantially constant thickness, and each elongated conducting element comprises a substantially constant width along a length of the elongated conducting element. A spacing between at least two of the elongated conducting elements is substantially constant. After installing the solderless compression connector, the elongated conducting elements are housed substantially within the respective chambers.

Abstract: A disk drive is disclosed comprising a plurality of disk surfaces, and a plurality of heads actuated over the respective disk surfaces. In one embodiment, control circuitry generates a pulse duty cycle signal for one of the heads. In another embodiment, the control circuitry generates a first pulse width modulated signal for a first head, and a second pulse width modulated signal for a second head, wherein the second pulse width modulated signal comprises a phase offset from the first pulse width modulated signal.

Abstract: A disk drive is disclosed comprising a disk, a head actuated over the disk, a preamp, and an interconnect for coupling the head to the preamp. The interconnect comprises a first transmission line stacked with a second transmission line, and a dielectric between the first transmission line and second transmission line. The transmission lines form an approximation of at least one inductor/capacitor ladder network and an approximation of at least one inductor/capacitor lattice network. The lattice network comprises a first leg and a second leg, and a cross-over hub for interconnecting the first leg and the second leg.

Abstract: A disk drive comprising a disk, and a head actuated over the disk, the head comprising a read element and a write element. The disk drive further comprises a preamp and an interconnect comprising a first transmission line and a second transmission line coupling the head to the preamp. A compensation network is disclosed operable to compensate for an impedance discontinuity in the first and second transmission lines, the compensation network comprising a first trace and a second trace connected in parallel with the first and second transmission lines, wherein a shape of the first and second traces varies to form at least a first capacitor.

Abstract: A method and system for providing an energy assisted magnetic recording (EAMR) disk drive are described. The disk drive includes a magnetic recording media, a pre-amplifier, an EAMR head, and at least one clock recovery circuit. The pre-amplifier provides a write current signal and a write gate signal for providing power to the EAMR head. The EAMR head includes at least one write transducer and at least one laser. The write transducer(s) are coupled with the pre-amplifier and include at least one writer coil. The write current signal from the pre-amplifier drives the writer coil(s). The clock recovery circuit(s) are coupled with the laser(s). The clock recovery circuit(s) receive the write current signal and the write gate signal and output laser control signal(s) that energize the laser(s) such that the laser(s) are energized synchronously with the writer coil(s).

Abstract: Disclosed herein are embodiments directed to a head gimbal assembly including a novel suspension assembly that includes a flexure tail with a first plurality of apertures in its structural layer. Each of the first plurality of apertures underlies a first trace but not a second trace. Each of a second plurality of apertures in the structural layer underlies a second trace but not the first trace. Each of the first plurality of apertures includes a corresponding region of maximum width, and each of the second plurality of apertures includes a corresponding region of maximum width, as measured in the width direction. None of the corresponding regions of maximum width of the first plurality of apertures is disposed in an overlapping position along the long axis as any of the corresponding regions of maximum width of the second plurality of apertures.

Abstract: A novel suspension assembly includes a flexure tail with a first plurality of apertures in its structural layer. Each of the first plurality of apertures underlies a first trace but not a second trace. Each of a second plurality of apertures in the structural layer underlies a second trace but not the first trace. Each of the first plurality of apertures includes a corresponding region of maximum width, and each of the second plurality of apertures includes a corresponding region of maximum width, as measured in the width direction. None of the corresponding regions of maximum width of the first plurality of apertures is disposed in an overlapping position along the long axis as any of the corresponding regions of maximum width of the second plurality of apertures.

Abstract: A disk drive comprising a disk, and a head actuated over the disk, the head comprising a read element and a write element. The disk drive further comprises a preamp and an interconnect comprising a first transmission line and a second transmission line coupling the head to the preamp. A compensation network is disclosed operable to compensate for an impedance discontinuity in the first and second transmission lines, the compensation network comprising a first trace and a second trace connected in parallel with the first and second transmission lines, wherein a shape of the first and second traces varies to form at least a first capacitor.

Abstract: A disk drive is disclosed comprising a disk, a head actuated over the disk, and control circuitry operable to estimate a fly height of the head by tuning a phase locked loop (PLL) in response to a fly height capacitance. In one embodiment, the PLL comprises a resistive component having a second terminal coupled to the fly height capacitance, a variable oscillator operable to generate a first oscillating signal applied to a first terminal of the resistive component to generate a second oscillating signal at the second end of the resistive component, and a phase detector operable to generate a control signal by comparing a phase of the first oscillating signal to a phase of the second oscillating signal. The control signal is applied to the variable oscillator to adjust a frequency of the first oscillating signal.

Abstract: Presently, almost all commercially available data storage systems use saturation recording and binary signaling schemes. Earlier data channels for storage systems utilized various forms of bit by bit peak detection. More recently, various forms of PRML (partial response maximum likelihood) or DFE (decision feedback equalization) have appeared in products. These improvements are still limited by the fact that the storage data channel is a saturation channel, and as such, has a significantly reduced information handling capacity compared to a linear data channel. Recording media defects are currently mapped out at the factory and skipped under normal device usage, while remaining errors are corrected by error correction code. However, at higher aerial densities, defects in the media tend to become a greater problem. The above-incorporated applications teach a linearization technique for linearizing magnetic recording channels without suffering signal to noise loss and not suffering bandwidth loss.

Abstract: A data storage system achieves improved bandwidth efficiency using a modulated recording signal, channel linearization, and a compressor circuit for compressing peak amplitude of the recording signal. In a preferred embodiment, quadrature amplitude modulation and demodulation is utilized. Another embodiment achieves improved bandwidth efficiency using a recording medium having a substantially rectangular magnetic flux versus magnetic field intensity hysteresis characteristic and a substantially rectangular Kerr rotation versus magnetic field intensity hysteresis characteristic. Yet another embodiment achieves improved bandwidth efficiency using a storage medium having a substantially abrupt flux transition.

Abstract: A more linear duty cycle modulator is made by converting the sine wave bias into a triangle wave bias utilizing a sample and hold circuit as the base band signal is added; on readout, low pass filtering of the high frequency content of the duty cycle modulated waveform, the base band signal is recovered at full amplitude as if saturation recording was being utilized. In a further preferred approach, quadature amplitude modulation and demodulation is utilized.

Abstract: A magneto-optical recording system achieves improved bandwidth efficiency using a modulated recording signal, recording channel linearization, and a MO medium having a low inter-granular exchange coupling and abrupt flux transitions.

Abstract: An apparatus and method for detecting defects in the magnetic medium of a disk drive system includes sampling the output signal of the read channel of the system to provide a sampled output signal. In one embodiment, the sampled output signals from the read channel is squared. A delayed sampled output signal is also provided. The squared sampled output signal is summed with the delayed squared output signal. The square of the expected value of the sum of the squared sampled output signal and the delayed squared output signal is subtracted from the sum to provide a difference output signal. A threshold detector determines when the difference output signal of the subtraction means exceeds a predetermined threshold to provide an output signal indicative of a defect in the medium. One threshold detector determines when the absolute value of the difference output signal exceeds a predetermined threshold value.

Abstract: An improved data recording system incorporates a detection circuit directly into the data read channel circuitry of the recording system to provide the capability of automatic self-testing and mapping of media flaws. The flaw detection circuit outputs an error signal in response to distortions in the readback signal caused by a defect on the medium. Firmware code is utilized for controlling the scanning of the medium by the flaw detection circuit and for recording the locations of the defects on the medium in response to the error signal. The detection circuit itself comprises a phase-splitter for splitting the readback signal into in-phase and quadrature-phase components. These components are then squared and summed to generate a phase independent flaw signal having an amplitude modulated in relation to the locations of the defects.