78results about "H-bridge head driver circuit" patented technology

A disk drive is disclosed comprising a voice coil motor (VCM) driver including an H-bridge driver having a first sense resistor connected in series with a supply voltage and a second sense resistor connected in series with ground. First and second amplifiers amplify the voltages across the first and second sense resistors, wherein the output of the amplifiers drive respective first and second oscillators. A counter processes the frequency signals output by the oscillators to generate a digital representation of the current flowing through the voice coil of the VCM.

A method and circuit are disclosed for controlling the write head of a magnetic disk storage device. The circuit includes a pull-up device coupled to a terminal of the write head, a current sink circuit which is coupled to the write head terminal and a bootstrap circuit coupled to the current sink circuit. When reversing the direction of current flow through the write head so that current is drawn from the write head from the write head terminal, the bootstrap circuit and the current sink circuit are activated. When the current in the write head nears and / or slightly surpasses the desired destination current level, the bootstrap circuit is deactivated and the pull-up device is thereafter immediately activated for a predetermined period of time.

A circuit is adapted to activate a writer head of a data storage media drive during both the boost periods as well as the steady state periods. The current supplied to the writer head during the boost periods exceeds the steady state current and flows between positive and negative voltage supplies so as to provide the required magnetic flux change in the inductor disposed in the write head. During the steady state periods, a switch circuit is turned on to provide a second current path across the writer head. During the steady state periods, the current flows between the positive voltage supply and the ground to reduce power consumption. The switch circuit is turned off during the boost periods.

A write driver (11) for a disk drive system is disclosed. The write driver (11) includes a normal H-bridge drive circuit (30) and a boost H-bridge drive circuit (32). The normal and boost H-bridge drive circuits (30, 32) are both biased from a Vcc power supply; however, system ground (GND) biases the normal H-bridge drive circuit (30), while a Vee power supply voltage, which is negative relative to system ground (GND), biases the boost H-bridge drive circuit (32). Diodes (46Y, 46X) are provided in the pull-down paths of the normal H-bridge drive circuit (30). During the boost portion of the write cycle, both of the normal and boost H-bridge drive circuits (30, 32) are on, and the pull-down current from the write head (HD) is conducted to the Vee power supply voltage. After the boost portion of the cycle, and thus after the desired overshoot current has been applied, only the normal H-bridge drive circuit (30) drives the steady-state write current, which is conducted to system ground (GND).

A circuit and method are disclosed for relatively rapidly causing the current flowing through a write head to transition between steady states without generating an appreciable amount of capacitively-coupled noise. Embodiments of the present invention generally provide drive voltage signals to the write head that have no common mode voltage levels during transitions between steady state current levels in the write head. In other words, the drive voltage signals applied to the write head are substantially entirely differential during write head current transitions. In an exemplary embodiment of the present invention, a driver circuit includes switching circuitry connected between the terminals of the write head and reference voltage supplies, such as positive and negative voltage supplies. The driver circuit further includes timing circuitry that generates control signals for controlling the switching circuitry.

The present invention covers circuits to achieve high data rate writing.

A method and circuit is disclosed for controlling the write head of a magnetic disk storage device. The circuit includes a pull-up device coupled to a terminal of the write head, for selectively providing a current to the write head through the terminal. The circuit further includes parallel-connected first and second current sink circuits, each of which is coupled to the write head terminal and selectively activated to draw current from the write head via the write head terminal. The circuit further includes a control circuit for individually activating the pull-up device and the first and second current sink circuits. In particular, when reversing the direction of current flow through the write head from a first direction in which current is provided to the write head via the write head terminal to a second direction in which current is drawn from the write head from the write head terminal, both the first and second current sink circuits are activated by the control circuit. When the current in the write head nears the desired destination current level, the second current sink circuit is deactivated and the pull-up device is thereafter immediately activated for a predetermined period of time. The pull-up device is deactivated as the current in the write head approaches a constant value. Due to the deactivation of the second current sink circuit and the temporary activation of the pull-up device, current overshoot and undershoot of the write head current is minimized.

A write driver circuit selectively provides a write current through a write head in first and second opposite directions. The write driver circuit is connected to the write head through an interconnect. The write driver circuit provides an incident write current signal through the interconnect to the write head, and also provides a reflection cancellation signal through the interconnect to the write head. In an exemplary embodiment, the incident write current signal is provided by providing an incident voltage signal across the write head, and the reflection cancellation signal is provided by providing a reflection cancellation voltage signal across the write head. In an exemplary embodiment, the reflection cancellation signal is a delayed and filtered version of the incident write current signal that cancels a reflected signal that is reflected at the interface between the interconnect and the write head due to impedance mismatching.

An open write head detection circuit is provided comprising a write head driver circuit, a programmable reference voltage source, a comparator and a pulse width filter. The write head driver circuit generates an voltage sense signal. The comparator compares the voltage sense signal with a reference voltage from the programmable reference voltage source and generates a comparator output signal indicative of whether the voltage sense signal is greater than or less than the reference voltage. The comparator output signal is input to the pulse width filter which generates a latched open head signal in response the voltage sense signal being less than the reference level for a predetermined time measured as a programmable number of write clock cycles.

A write driver apparatus and corresponding method for an inductive head element (20) in a magnetic storage medium, such as a hard disk drive, having an H-bridge type circuit (10) which is capable of driving a current through the inductive head element (20) and having a boost circuit (250, 260) which is coupled with the H-bridge (10) and which is operable for delivering another current during a predetermined period to the head element (20), wherein a sum of the currents provides the write current for the head element (20) of the hard disk drive. Further, a resistive element (210, 320, 330) is selectively coupled with the head element (20) for providing impedance matching in which the resistive element (210, 320, 330) is decoupled from the head element (20) during delivery of the current from the boost circuit (250, 260).

A method is disclosed for controlling the write head of a magnetic disk storage device. The method includes sinking current from the first terminal of the write head and sourcing current to the second terminal of the write head substantially simultaneously with sinking current from the first terminal so that a first steady state voltage level appears on the first terminal of the write head and a second steady state voltage level appears on the second terminal thereof that are approximately at a midpoint between a high reference voltage level and a low reference voltage level. The common mode voltage of the write head is substantially constant over time.

A dual-mode positioning driver (32) for a voice coil motor (22) in a disk drive system (10) is disclosed. Linear prestage drivers (38) and pulse-width-modulated prestage drivers (46) are both coupled to power transistors (50) arranged in an “H” bridge for driving the voice coil motor (22). The positioning driver (32) is thus operable to drive the power transistors (50) in either a linear mode or a pulse-width-modulated class D mode. In a transition period while switching from the pulse-width-modulated mode to linear mode, comparators (56H, 56L) compare the phase voltages in the “H” bridge with a reference voltage. The outputs of the comparators (56H, 56L) are applied to the PWM output amplifiers (54H, 54L) to drive the power transistors (50), so that the phase voltages are preconditioned toward their linear bias points. Discontinuities in the drive current through the voice coil motor (22) are minimized as a result.

A recording head drive circuit drives a recording head that records information on a magnetic recording medium. A switching circuit is a H-bridge circuit which includes a plurality of transistors. The switching circuit switches direction of a write current (Iw) flowing in the recording head, in accordance with a conduction state of each transistor. A write current controller controls the write current (Iw) in the recording head. An overshoot control circuit adds an overshoot current (Ios), proportional to the write current (Iw), to the write current (Iw) flowing in the recording head, in a predetermined overshoot time period.

A booster boosts a power voltage of a disk storage apparatus. The voltage obtained by boosting the power voltage is applied to a write driver in a head IC via a power line as a power voltage for the write driver. The power voltage of the disk storage apparatus is applied to a read amplifier in the head IC.

A magnetic recording apparatus suitable for high-density and high-frequency magnetic recording includes a recording head to the coil of which a recording current is supplied, the recording current having a waveform such that the conducting time length is shorter than the time length of a recording pattern.

A hard disk drive write driver circuit is described that can change the output impedance of the write driver by use of a lookup table of control values. A control value is selected from the lookup table by using an address based on a dynamic system variable and a program controlled value. The dynamic system variable is converted to a digital representation. The digital representation and a portion of the program controlled value are used as an address to the lookup table to select a control value. The write driver is responsive to the selected control value to control overshoot current. A method to digitally program the output impedance of a preamp write driver based on realistic operating data is also discussed. An additional approach to controlling overshoot current in a write driver through digital control of overshoot duration is also described.

A write driver 100, 200, 300 is implemented to provide near-ground common mode output voltages to produce a more symmetrical head voltage swing (i.e. ±0.4V from ground to ±5V supply voltages). These features help to reduce the effects of common mode impedance associated with the interconnection to the disk drive head to improve overall performance. Lower jitter at high data rates can be achieved when compared to prior art techniques for implementing current mode write drivers. Further, the matched impedance between the write driver 100 and the interconnection 106 eliminates unwanted reflections. ECL level voltage swings (200-500 mV) have replaced more conventional CMOS level voltage swings (5V) to further reduce overall power dissipation associated with the write driver. The small ECL level switching further maintains constant power dissipation with changes in operating frequency and results in less NTLS effects due to quieter supplies.

A driver for driving a load over a transmission line, such as driving the magnetic head of a hard disk drive. The driver includes a signal switch for switching the signal to the load during a signal period, and a boost switch for boosting the signal during a boost period, so as to decrease rise time of the signal at the load by deliberately injecting an overshoot. A switchable protection device protects the signal switch and the boost switch. The protection device includes a reflection-suppression switch which is pulsed during a time corresponding to the expected return of a reflection corresponding to the overshoot signal, so as to force the protection device into saturation mode. Since the protection device is in the saturation mode during the return reflection of the boost signal, the returned reflection sees a matched impedance and thus reduces a re-reflection back to the load.

The present invention discloses an apparatus (160) comprising a common mode generator circuit (162) coupled to a current directing circuit adapted to provide current to a first write head connection node (170) and to a second write head connection node (172). The common mode generator circuit (162) is adapted to provide additional current to the first write head connection node (170) and to the second write head connection node (172), wherein the first write head connection node (170) is adapted to produce a first write signal, wherein the second write head connection node (172) is adapted to produce a second write signal, wherein the current and the additional current are adapted to establish a voltage across the first write head connection node (170) and the second write head connection node (172), wherein the voltage is adapted to be pulled toward a first polarity based on the first write signal and toward a second polarity based on the second write signal, and wherein the voltage pulled toward the first polarity and the voltage pulled toward the second polarity are substantially centered about a common mode voltage.