According to one embodiment, a method for mounting a wireless capture device to an accessor to capture images of an operation in a data storage library includes mounting a bracket to the accessor, where the accessor is configured to transport data storage cartridges in a library environment. Moreover, the bracket is configured to receive a wireless image capture device therein, and the bracket is mounted in a position to orient the wireless image capture device to capture images while the accessor is transporting data storage cartridges.

Embodiments disclosed herein provide systems, methods, and computer readable media to handle unsuccessful movements of removable storage media in an automated removable media system. In a particular embodiment, a method provides receiving one or more user provided parameters that indicate one or more types of unsuccessful media move operations that should be reported as successful. The method further provides receiving a first request to move a first item of removable storage media from a first position in the automated removable media system to a second position in the automated removable media system and initiating a first move operation of the first item from the first position to the second position by at least one changer device. The method then provides determining that the first move operation resulted in one of the one or more types of unsuccessful media move operations and indicating that the first move operation was successful in response to the first request.

The system includes a base frame and a controller attached to the base frame. An access point is attached to the controller. The base frame includes a plurality of tape drive slots. A plurality of frames are attached to the base frame. Each frame in the plurality of frames includes a plurality of tape slots. A tape cartridge is stored in a tape slot. An x-y-z movement system is connected to the base frame and the plurality of frames. A wireless network is connected to the base frame.

The present description is directed to moving a cartridge including a storage medium within a shuttle complex that includes numerous shuttle connections, and a plurality of library strings connected by at least one shuttle connection. Each shuttle connection has a car able to move within the shuttle connection and each library string has at least one cartridge including a storage medium. The shuttle complex identifies a library string that contains the access-cartridge (LSAC), identifies whether there is a drive within the LSAC that has a second cartridge mounted therein which comprises only inactive data chunks, removes the second cartridge from the drive within the LSAC if an elapsed time since the drive within the LSAC most recently accessed the second cartridge exceeds a predetermined time period threshold, and mounts the access-cartridge to the drive within the LSAC.

The present description is directed to moving a car within a shuttle connection that connects a first library string and a second library string contained in a shuttle complex. The shuttle complex determines a first library string data chunk count of a first library string, determines a second library string data chunk count of a second library string, and moves the car within the shuttle connection to the first library string if the first library string data chunk count is greater than the second library string data chunk count. A library string data chunk count is generally the sum of respective cartridge data chunk counts of each cartridge located within the library string. The library string data chunk count may be updated after a data chunk write to a cartridge located within the library string, may be updated after a cartridge is moved from the library string, and may be updated after a cartridge is moved to the library string.

In one embodiment, a system includes a controller for controlling a robotic accessor, and a memory in communication with and/or integrated with the controller for storing information about media and storage slots. The information includes data corresponding to a physical distribution of the media in the storage slots. Logic integrated with and/or executable by the controller is configured to position the robotic accessor at a computed optimal position during an idle period of the robotic accessor, the computed optimal position being based at least in part on at least one of: (a) the data corresponding to the physical distribution of the media in the storage slots, and (b) a center of access calculated using the data corresponding to the physical distribution of the media in the storage slots.

In one embodiment, an apparatus includes an accessor configured to transport data storage cartridges in a library environment, and a bracket configured to receive a wireless image capture device therein where the bracket is positioned to orient the wireless image capture device to capture images while the accessor is transporting data storage cartridges. In another embodiment, a method for mounting a wireless capture device to an accessor to capture images of an operation in a data storage library includes mounting a bracket to the accessor, where the accessor is configured to transport data storage cartridges in a library environment, where the bracket is configured to receive a wireless image capture device therein. The bracket is mounted in a position to orient the wireless image capture device to capture images while the accessor is transporting data storage cartridges.

A data storage library system and method comprising at least one data storage library, the at least one data storage library comprising one or more library frames associated with the one or more library frames and at least one environmental conditioning unit configured to control one or more environmental conditions within the one or more library frames. At least one component locker is housed in an interior portion of the one or more library frames, and the at least one component locker is configured to retain one or more replacement components for use in the at least one data storage library.

A tape library system includes a plurality of tape libraries, a plurality of data centers, and an error diagnostic system. Each of the plurality of tape libraries includes a tape drive, at least one tape cartridge that retains magnetic tape, and a tape cartridge mover that moves the tape cartridge relative to the tape drive. Each of the plurality of data centers is configured to retain at least one of the plurality of tape libraries. The error diagnostic system includes (i) a central database that is configured to receive one or more error codes from each of the plurality of tape libraries, each of the one or more error codes being generated due to errors that occurred during operation of the tape drive within a corresponding tape library, and (ii) a system controller including a processor that is configured to analyze the one or more error codes from each of the plurality of tape libraries to determine a health of the tape drive and the at least one tape cartridge within the corresponding tape library.

The system includes a base frame and a controller attached to the base frame. An access point is attached to the controller. The base frame includes a plurality of tape drive slots. A plurality of frames are attached to the base frame. Each frame in the plurality of frames includes a plurality of tape slots. A tape cartridge is stored in a tape slot. An x-y-z movement system is connected to the base frame and the plurality of frames. A wireless network is connected to the base frame.