The present disclosure generally relates to a tape head and a tape drive including a tape head. The tape head comprises a first same gap verify (SGV) head assembly comprising a first media facing surface (MFS) and a plurality of first write transducer and first read transducer pairs, and a second SGV head assembly comprising a second MFS and a plurality of second write transducer and second read transducer pairs. During operation, when a tape or magnetic media moves in a first direction over the tape head, the tape contacts the second MFS and is spaced from the first MFS, and when the tape moves in a second direction opposite the first direction over the tape head, the tape contacts the first MFS and is spaced from the second MFS. As such, the tape contacts only one edge of either the first or second MFS during operation.

According to one embodiment, a magnetic head includes a protective layer. When an element unit is a magnetic recording element unit, the protective layer includes a first region on a magnetic recording element protrusion and a second region on a magnetic recording element shield, the first region and the second region being flush with each other, or the first region being recessed more than the second region. When the element unit is a magnetic reading element unit, the protective layer includes a third region on a magnetic reading element protrusion and a fourth region on a magnetic reading element shield, the third region and the fourth region being flush with each other, or the third region being recessed more than the fourth region.

Provided are a magnetic tape head, a magnetic tape drive, and a computational device in which the magnetic tape head is comprised of a plurality of elements, wherein a pitch between adjacent elements of the plurality of elements is not identical. Selected elements of the plurality of elements that are shifted from a nominal position are selected in a symmetrical manner in the plurality of elements. A total of shifts of the elements of the plurality of elements that are shifted add up to a desired total shift to realign a plurality of modules, such that the median head span of each module type match as closely as possible to a desired value of a head span for all module types.

According to one embodiment, a magnetic head includes a protective layer. When an element unit is a magnetic recording element unit, the protective layer includes a first region on a magnetic recording element protrusion and a second region on a magnetic recording element shield, the first region and the second region being flush with each other, or the first region being recessed more than the second region. When the element unit is a magnetic reading element unit, the protective layer includes a third region on a magnetic reading element protrusion and a fourth region on a magnetic reading element shield, the third region and the fourth region being flush with each other, or the third region being recessed more than the fourth region.

The present disclosure generally relates to a head assembly of a data storage device. The data storage device may include magnetic media embedded in the device or magnetic media from an insertable cassette or cartridge (e.g., in an LTO drive), where the magnetic head assembly reads from and writes to the magnetic media. During drive operation, the magnetic media moves across the magnetic head assembly. The magnetic head assembly is spaced a distance from the magnetic media such that non-contact recording occurs between the magnetic head assembly and the magnetic media. The magnetic media is supported by either a back plate or an air film generated by one or more fillet edges of the back plate and the velocity of the magnetic media as the magnetic media moves across the magnetic head assembly.

A magnetic device including: a magnetic reader; a magnetic writer; and a variable overcoat, the variable overcoat positioned over at least the magnetic reader and writer, the variable overcoat having an overcoat layer, the overcoat layer having a substantially constant thickness and material; and at least one disparate overcoat portion, the disparate overcoat portion having a different thickness, a different material, or both, than the overcoat layer.

Embodiments are disclosed for a method. The method includes determining a reference plane for a tape drive read-write array. The tape drive read-write array includes a first array element, a predetermined array element, and a last array element. Further, determining the reference plane is based on a first array position of the first array element and a last array position of the last array element. The method also includes capturing a position of a predetermined array element using an imaging device. The method further includes determining a deviation of the captured position from the reference plane. Additionally, the method includes generating a plot of an in-plane bow based on the deviation.

Provided are a magnetic tape head, a magnetic tape drive, and a computational device in which the magnetic tape head is comprised of a plurality of elements, wherein a pitch between adjacent elements of the plurality of elements is not identical. Selected elements of the plurality of elements that are shifted from a nominal position are selected in a symmetrical manner in the plurality of elements. A total of shifts of the elements of the plurality of elements that are shifted add up to a desired total shift to realign a plurality of modules, such that the median head span of each module type match as closely as possible to a desired value of a head span for all module types.

Provided are a magnetic tape head, a magnetic tape drive, and a computational device in which the magnetic tape head is comprised of a plurality of elements, wherein a pitch between adjacent elements of the plurality of elements is not identical.

According to one embodiment, a magnetic disk device includes a magnetic disk, a magnetic head including a read head, a write head, a heater and the magnetic head, and a sensor and the control section. The control section when applying electric power to the heater, the control section predicts, on the basis of a relationship between a value of the electric power to be applied to the heater and an output value of a spectrum at a pulse frequency of a DC output of the sensor in a state where pulsed electric power is applied to the heater, the output value of the spectrum, and detects contact between the magnetic head and the magnetic disk before the predicted output value of the spectrum becomes less than or equal to a threshold.