A magnetic disk device includes a magnetic disk, a first read element, a second read element, and a controller. In the magnetic disk, first servo information is written. The controller controls the servo writing of second servo information on the magnetic disk, based on the first servo information. In addition, the controller controls acquisition of the first servo information by the first read element. The controller switches a read element to be used to control the servo writing from the first read element to the second read element based on quality of the first servo information acquired by the first read element.

A data storage device comprising a first actuator configured to actuate a first head over a first disk surface, and a second actuator configured to actuate a second head over a second disk surface. A plurality of access commands are received from a host, and a cost metric is computed for executing a seek to execute each access command of the plurality of access commands, wherein the cost metric is based on an access latency of the seek, a power consumption of the seek, and an estimated combined current draw of the first and second actuators during the seek. The access commands are sorted into an execution order based on the cost metrics computed for the access commands.

According to one embodiment, a manufacturing method of a magnetic disk device including a magnetic disk that stores information, and two or more control devices is provided. The method includes acquiring power consumption of each of a plurality of control devices to be able to be included in the magnetic disk device; and selecting a combination of two or more control devices to reduce variation in total power consumption, on the basis of the acquired power consumption.

An apparatus, according to one embodiment, includes at least two write transducers positioned a predefined distance apart in a first direction. Outer surfaces of pole tips of the write transducers are substantially coplanar. Write gaps are defined between the pole tips of the write transducers. Planes of the write gaps are oriented substantially perpendicular to the first direction. Coils are positioned to create flux in a magnetic yoke of each write transducer upon energization thereof. The apparatus also includes a mechanism for assisting in orienting a module having two or more sensors of interest relative to the write gaps.

An apparatus, according to one embodiment, includes at least two write transducers positioned a predefined distance apart in a first direction. Outer surfaces of pole tips of the write transducers are substantially coplanar. Write gaps are defined between the pole tips of the write transducers. Planes of the write gaps are oriented substantially perpendicular to the first direction. Coils are positioned to create flux in a magnetic yoke of each write transducer upon energization thereof. The apparatus also includes a mechanism for assisting in orienting a module having two or more sensors of interest relative to the write gaps.

A tape drive may calculate the slopes for three successive timing-based-servo marks in a timing-based-servo group. The timing-based-servo marks may be arranged in a one or more M-patterns. The three successive timing-based-servo marks may be across the one or more M-patterns. The tape drive may perform a parabolic fit of a gradient of the slopes. The tape drive may determine whether the gradient is demonstrative of tape-creep.

Implementation of a non-interfering micro-positioning device, for a tape drive write/read head module assembly utilizing piezoelectric elements, by generating at least two flexure brackets. The at least two flexure brackets may include the piezoelectric elements. Affixing at least one flexure bracket to a first side of the write/read head module assembly. Affixing at least one other flexure bracket to a second side of the write/read head module assembly.

A temperature measuring unit includes a base including a first face, a second face on a side opposite to the first face, and a first opening portion penetrating the first face and the second face, a support member including a body portion provided on the second face side to overlap with the first opening portion, and a plurality of extending portions extending from the body portion along the second face and overlapping with the second face, and a thermocouple inserted into the first opening portion and including a measuring portion located on the body portion.

A tri-stage actuated disk drive suspension is described. The tri-stage actuated disk drive suspension including a beam and a gimbal attached to the beam. The gimbal is configured to receive a first actuator to mount on a first surface of the suspension near a first lateral side of the suspension and is configured to receive a second actuator to mount on the first surface of the gimbal near a second lateral side of the suspension. The gimbal is configured to receive a head slider to mount on the first surface of the suspension. And, the tri-stage actuated disk drive suspension including a baseplate having the beam attached thereto. The baseplate configured to receive a third actuator from the first surface of the suspension to mount on a pair of shelves.

In an approach to HRTD recovery by writing the HRTD in a null data set, responsive to receiving a request to write a data set to a magnetic tape, a lead data set of a current wrap of a plurality of wraps of the magnetic tape is written, wherein the lead data set of the current wrap includes a current wrap HRTD that contains one or more directory records for each wrap of the plurality of wraps from a lead wrap of the plurality of wraps through a first prior wrap of the plurality of wraps, and further wherein the first prior wrap immediately precedes the current wrap.