A tape reader is provided that reads data from a tape without requiring specific alignment. The tape reader may include a reader head comprising a sensor array with a plurality of sensors that detect the data independent of the track within which the data is stored. Multiple sensors may detect data in each track instead of a single, dedicated sensor for each track. The sensor array may comprise multiple sensors in multiple dimensions, such as perpendicular to the movement of the tape or in parallel to the movement of the tape, including serpentine linear recording formats where the sensors may be in a matrix positioned at various angles from horizontal to vertical.

A tape reader is provided that reads data from a tape without requiring specific alignment. The tape reader may include a reader head comprising a sensor array with a plurality of sensors that detect the data independent of the track within which the data is stored. Multiple sensors may detect data in each track instead of a single, dedicated sensor for each track. The sensor array may comprise multiple sensors in multiple dimensions, such as perpendicular to the movement of the tape or in parallel to the movement of the tape, including serpentine linear recording formats where the sensors may be in a matrix positioned at various angles from horizontal to vertical.

A set of encoded data fragments is grouped into a container object in sequential order. Each encoded data fragment is a specific fragment size, and the container object is a specific container object size. The sequential order of the set of encoded data fragments can be tracked in a log in memory, such that the location of any one of the data fragments in the container object can be determined. The container object can be stored directly on a specific backend storage element, without using a file system. A corresponding container object identifier identifies the physical storage location of the container object on the backend storage element. The container object identifier is tracked in the log in memory, such that the physical location on the backend storage element of any specific one of the set of encoded data fragments in the container object can be determined.

As disclosed herein a method for encoding information on tape using write offset gaps. The method includes receiving a request to write a dataset on a tape medium using a plurality of head groups, and identifying information to be encoded when writing the dataset. The method further includes determining a head group offset pattern that encodes the information, and writing the dataset using the head group offset pattern. Also disclosed herein is a method for decoding information on tape using write offset gaps. The method includes reading a dataset from a tape medium using a plurality of head groups, and determining a head group offset pattern used to read the dataset. The method further includes decoding information encoded in the head group offset pattern to provide decoded information. A computer program product corresponding to the above method is also disclosed herein.

A tape reader is provided that reads data from a tape without requiring specific alignment. The tape reader may include a reader head comprising a sensor array with a plurality of sensors that detect the data independent of the track within which the data is stored. Multiple sensors may detect data in each track instead of a single, dedicated sensor for each track. The sensor array may comprise multiple sensors in multiple dimensions, such as perpendicular to the movement of the tape or in parallel to the movement of the tape, including serpentine linear recording formats where the sensors may be in a matrix positioned at various angles from horizontal to vertical.

A tape reader is provided that reads data from a tape without requiring specific alignment. The tape reader may include a reader head comprising a sensor array with a plurality of sensors that detect the data independent of the track within which the data is stored. Multiple sensors may detect data in each track instead of a single, dedicated sensor for each track. The sensor array may comprise multiple sensors in multiple dimensions, such as perpendicular to the movement of the tape or in parallel to the movement of the tape, including serpentine linear recording formats where the sensors may be in a matrix positioned at various angles from horizontal to vertical.

A method for writing a servo pattern to a magnetic tape medium includes orienting a magnetic flux in opposite directions across gaps in the magnetic tape medium, and moving the magnetic tape medium with its servo band above two gaps in a direction along a longitudinal extension of the magnetic tape medium. The magnetic tape medium includes a servo band along the longitudinal extension of the magnetic tape medium and a servo pattern organized in a servo frame with a first burst having at least two servo stripes, and a second burst having at least two servo stripes. For at least one of the first and second bursts, different stripes within a same burst have opposite magnetic polarities with respect to one another. The method further includes applying a current pulse to the coil, moving the magnetic tape medium, and applying another current pulse to the coil.

A method for writing a servo pattern to a magnetic tape medium includes orienting a magnetic flux in opposite directions across gaps in the magnetic tape medium, and moving the magnetic tape medium with its servo band above two gaps in a direction along a longitudinal extension of the magnetic tape medium. The magnetic tape medium includes a servo band along the longitudinal extension of the magnetic tape medium and a servo pattern organized in a servo frame with a first burst having at least two servo stripes, and a second burst having at least two servo stripes. For at least one of the first and second bursts, different stripes within a same burst have opposite magnetic polarities with respect to one another. The method further includes applying a current pulse to the coil, moving the magnetic tape medium, and applying another current pulse to the coil.

A magnetic tape device includes a magnetic tape as a storage medium; a travel unit that moves the magnetic tape along a travel route; a magnetic head that is arranged at the travel route and performs data reading and writing for the magnetic tape that moves on the travel route; and a lifter unit that is arranged at the travel route and contacts the magnetic tape which is stopped on the travel route, where the lifter unit is able to reciprocate in a direction that intersects the travel route so as to separate the magnetic tape from the magnetic head.

As disclosed herein a method for encoding information on tape using write offset gaps. The method includes receiving a request to write a dataset on a tape medium using a plurality of head groups, and identifying information to be encoded when writing the dataset. The method further includes determining a head group offset pattern that encodes the information, and writing the dataset using the head group offset pattern. Also disclosed herein is a method for decoding information on tape using write offset gaps. The method includes reading a dataset from a tape medium using a plurality of head groups, and determining a head group offset pattern used to read the dataset. The method further includes decoding information encoded in the head group offset pattern to provide decoded information. A computer program product corresponding to the above method is also disclosed herein.