A computer-implemented method includes initiating a copy request for a data storage cartridge. The data storage cartridge includes data storage media having host data thereon. The method also includes transparently loading the data storage cartridge into a first data storage drive of a data storage library and establishing drive-to-drive communication for copying data from the data storage media in the first data storage drive to data storage media in a second data storage drive. The method includes copying data from the data storage media in the first data storage drive to the data storage media in the second data storage drive. A system includes a processor and logic integrated with the processor, executable by the processor, or integrated with and executable by the processor. The logic is configured to perform the foregoing method.

The technology disclosed herein enables automatic implementation of a physical barrier to protect access to data on removable storage media. In a particular embodiment, a method provides determining that the item moved into a storage position using an automatic transfer mechanism and determining that a condition for protecting the item is satisfied. Upon determining that the condition is satisfied, the method provides implementing a physical barrier that prevents the automatic transfer mechanism from removing the item from the storage position.

A tape may be mounted into a tape drive. Mounting the tape into the tape drive may include loading the tape from a storage slot. The tape drive may request a first record of the tape from a tape storage subsystem. The tape drive may determine whether the first record of the tape exists in the tape storage subsystem. The tape drive may load the first record of the tape in random access memory (RAM) of the tape drive. The first record may include one or more data entries. The tape drive may append a new data entry to the first record. The first record may be transitioned to a second record upon being appended with the new data entry. The tape may be unmounted from the tape drive.

A cartridge management system that manages a plurality of cartridges, in each of which a magnetic tape is housed, includes a processor, and a memory incorporated in or connected to the processor, in which the processor is configured to execute data rewrite-in processing of rewriting data stored in the magnetic tape, in a specific cartridge among the plurality of cartridges based on an access frequency indicating a frequency of access to the data, and cartridge replacement processing of replacing the data stored in the magnetic tape of the specific cartridge and the data stored in the magnetic tape of another cartridge among the plurality of cartridges.

The technology disclosed herein enables automatic implementation of a physical barrier to protect access to data on removable storage media. In a particular embodiment, a method provides determining that the item moved into a storage position using an automatic transfer mechanism and determining that a condition for protecting the item is satisfied. Upon determining that the condition is satisfied, the method provides implementing a physical barrier that prevents the automatic transfer mechanism from removing the item from the storage position.

In an approach for preventing damage to a tape library, a processor receives a first sensor reading, wherein the first sensor is located within a tape library. A processor receives a second sensor reading, wherein the second sensor is located external to the tape library. A processor determines that the second sensor reading is greater than or equal to the first sensor reading. A processor receives an indication that a door to the tape library is open. Responsive to receiving the indication that the door to the tape library is open, a processor disables a fan.

A tape library having a robot zone and a robot on the robot zone, movable in the robot zone of the tape rack in at least a first direction and a second direction. A tape drive, which has an opening to receive cartridges, is positioned so that the robot nears the tape drive when the robot moves in a second direction. A width of the tape drive is wider than a width of the robot zone. This tape drive design is called the “Sideways Format Path for 19″ Rack Libraries.” It is achieved by using unique dimensions for a new tape drive that uses blind spaces existing in tape libraries unreachable by the robot to provide a bigger space to design longer tape paths, resulting in higher cartridge density with longer tape path without requiring bigger overall library dimensions for a library of tape cartridges.

An apparatus for tape library management. The apparatus includes a storage slot that includes a plurality of mirrors integrated into the storage slot for reading a barcode affixed to each of a plurality of tape cartridges stored in a tiered orientation within the storage slot. The apparatus further includes wherein each of the plurality of mirrors are located directly below the barcode affixed to each of the plurality of tape cartridges stored in the storage slot. The apparatus further includes wherein each of the plurality of mirrors projects a reflection of the barcode affixed to each of the plurality of tape cartridges outward towards a front side of the storage slot.

A tape library apparatus includes a tape drive, a robot unit, and a second processor. The tape drive includes a first access mechanism and a first processor. The first access mechanism is configured to read position information from a non-contact type memory within a tape cartridge. The position information indicates a position of data recorded in a magnetic tape within the tape cartridge. The first processor is configured to perform positioning for the data. The robot unit includes a robot arm and a second access mechanism configured to access the non-contact type memory. The robot arm is configured to store the tape cartridge in the robot unit, and move the tape cartridge to the tape drive. The second processor is configured to control the second access mechanism to read the position information from the non-contact type memory, and store the position information in a non-volatile memory.

Embodiments are described for proximity auditing of removable media cartridge magazines in a data storage library. For example, a proximity sensor mounted on a robotic assembly can be used to detect one or more target features of cartridge magazines. In particular, the proximity sensor can look for relatively large structural features of a removable cartridge magazine in a manner that is fast and reliable, and does not rely on precise positioning of the robotic assembly with respect to the magazine. Some implementations can use the proximity sensor in conjunction with further auditing and/or other functions of line camera, and/or other sensors of the robotic assembly. Proximity-based auditing of the magazines can permit storage library systems to initialize faster and with more reliable inventory information.