A magnetic tape cartridge includes a case in which a magnetic tape is accommodated and a storage medium provided in the case. At least one of reading or writing of data is performed by a plurality of magnetic elements, which are linearly disposed, with respect to the magnetic tape pulled out from the case. A disposition direction of the plurality of magnetic elements is tilted toward an entire length direction side of the magnetic tape with respect to a width direction of the magnetic tape. The storage medium stores tilt feature information indicating a feature of tilt of the disposition direction with respect to the width direction.

Provided is a magnetic tape with the total thickness of a non-magnetic and magnetic layers is equal to or smaller than 0.60 μm, a C—H derived C concentration calculated from a C—H peak area ratio of C1s spectra by ESCA on the surface of the magnetic layer at a photoelectron take-off angle of 10 degrees is equal to or greater than 45 atom %, full widths at half maximum of spacing distribution measured by optical interferometry regarding the surface of the magnetic layer before and after vacuum heating with respect to the magnetic tape are respectively greater than 0 nm and equal to or smaller than 7.0 nm, and a difference between a spacing measured after the vacuum heating and a spacing measured before the vacuum heating is greater than 0 nm and equal to or smaller than 8.0 nm.

A processing device stores a result of reading a reference servo pattern by a servo reading element from a magnetic tape in which the reference servo pattern is recorded, in the storage medium as an ideal waveform signal indicating an ideal waveform, acquires a servo band signal which is a result of reading a servo pattern recorded in a servo band of the magnetic tape by the servo reading element, and detects a servo pattern signal which is a result of reading the servo pattern by the servo reading element by comparing the ideal waveform signal stored in the storage medium with the servo band signal. The magnetic tape has a data band. The reference servo pattern is recorded in the data band.

A computer-implemented method for altering a position on a tape at which the tape transitions to a DATA_FULL state is disclosed. The computer-implemented method further includes determining, after a file is written to a Data Partition of the tape, a size of an Index representing metadata associated with the file. The computer-implemented method further includes altering, based on the size of the Index representing metadata associated with the file, a position in the Data Partition of the tape at which the tape transitions to the DATA_FULL state.

A magnetic recording medium is a tape-shaped magnetic recording medium, including: a substrate; an underlayer provided on the substrate; and a magnetic layer provided on the underlayer. The substrate contains polyester, each of the underlayer and the magnetic layer contains a lubricant, the magnetic layer has a surface on which a large number of holes is provided, the arithmetic average roughness Ra of the surface is 2.5 nm or less, a BET specific surface area of the entire magnetic recording medium measured in a state where the magnetic recording medium has been washed and dried is 3.5 m.sup.2/g or more and 7.0 m.sup.2/g or less, a squareness ratio of the magnetic layer in a vertical direction is 65% or more, an average thickness of the magnetic layer is 80 nm or less, an average thickness of the magnetic recording medium is 5.6 μm or less, and a servo pattern is recorded on the magnetic layer and a statistical value δ.sub.SW indicating a non-linearity of the servo pattern is 24 nm or less.

The present disclosure is generally related to a tape head comprising a first module and a second module joined together along a seam. The first module comprises a plurality of data heads disposed in a first row parallel to the seam, and the second module comprises a plurality of data heads disposed in a second row parallel to the first row. The first row and the second row are spaced apart a distance of about 50 μm to about 175 μm. A via is disposed at a media facing surface (MFS) along a portion of the seam. The via has a length less than a width of the MFS and equal to or greater than a length of the first and second rows of data heads. The via is configured to create a vacuum effect to pull a magnetic media against the media facing surface when the tape head reads and writes data to the magnetic media.

A method according to one embodiment includes coupling closures to a section having a plurality of rows of transducers formed on a substrate, the closures being coupled to the section on an opposite side of the transducers as the substrate. The section is coupled to a lapping-resistant guide, where the closures protrude beyond a lap-stop end of the guide. The closures are lapped for shortening the closures in a direction toward the transducers, wherein the lapping is terminated after the guide contacts a lapping surface. A method according to another embodiment includes coupling closures to a section having a plurality of rows of transducers formed on a substrate. The closures are lapped for shortening the closures in a direction toward the transducers. An extent of the lapping is determined using an optical and/or a contact technique.

The present invention provides a method of partitioning a tape medium dynamically by using a new method of writing data. It enables users to change size of the partitions later and to use all capacity of a tape efficiently. When a tape is divided into partitions, data is written in such a manner that the wraps are written in the partitions of the data band alternately in the forward direction and in the backward direction on the data band from the different sides of the data band toward the inside of the data band (W1,W2,W3 . . . ) and the location (C) at which the wrap (Wm) of the one partition collides with the wrap (Wn) of the other partition is defined as the demarcation (PB) of these partitions (P0,P1).

A sequential storage media system may include a head for reading or writing data to sequential storage media and a controller communicatively coupled to the head. The controller may be configured to control winding of a tape comprising sequential storage media and cleaning media between reels of a cartridge comprising the tape in order to clean a head of a sequential storage media system by passing the cleaning media over the head, after cleaning the head of the sequential storage media system, monitor a bit error rate of input/output communication between the head and the sequential storage media, and repeat the cleaning and the monitoring steps responsive to the bit error rate exceeding a threshold.

A sequential storage media system may include a head for reading or writing data to sequential storage media and a controller communicatively coupled to the head. The controller may be configured to control winding of a tape comprising cleaning media between reels of a cartridge comprising the tape in order to determine an occurrence of an event indicative of a need to clean a head of a sequential storage media system, issue to a user an indication of the occurrence of the event, determine an amount of cleaning for the head based on a bit error rate of input/output communication associated with the head, and responsive to receiving a cleaning cartridge in the sequential storage media system, clean the head of a sequential storage media system in accordance with the amount of cleaning by passing cleaning media of a cartridge over the head.

A computer program product for orienting a head, according to one embodiment, includes a computer readable storage medium having program instructions embodied therewith that are readable/executable by a controller to cause the controller to determine a desired pitch for transducers of a magnetic head for reading and/or writing to a magnetic tape, and are readable/executable by the controller to cause the controller to cause a mechanism to orient the magnetic head towards first and second positions to achieve the desired pitch when the tape travels in first and second directions, respectively. Outer data transducers of the third array are about aligned with outer data transducers of the second array when the magnetic head is positioned towards the first position, and the outer data transducers of the third array are about aligned with outer data transducers of the first array when the magnetic head is positioned towards the second position.