Abstract:
A recording/playback recording medium comprising an elongated, flexible recording/playback medium having a predetermined width and a predetermined length, together defining a recording/playback area capable of providing a plurality of elongated recording/playback tracks; and information located on at least two tracks, a first track being recorded from the beginning of the first track in a first direction until the track is filled, a second track being recorded in a second opposite direction, the tracks being partitioned to define sectors having identifiable locations, the first, second, and subsequent tracks if necessary being recorded in a serpentine manner, the information recorded on the tracks being recorded by a helical scan.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
   This application is related to the subject matter of U.S. patent application Ser. No. 10/930,904, directed to a linear sliding scanner used to achieve the high-density recording pattern on the ultra fast backup recording medium according to this disclosure, and U.S. patent application Ser. No. 10/930,763, now U.S. Pat. No. 6,992,847 issued Jan. 31, 2006, directed to a spool cartridge for operatively housing the ultra fast backup recording medium recorded in the manner presented in this disclosure. 
   BACKGROUND OF THE INVENTION 
   1. Technical Field of the Invention 
   This invention relates generally to a recording medium, such as a tape, and preferably an Advanced Intelligent Tape (“AIT”), for use in an Ultra Fast Backup (“UFB”) format in a fast access data storage system. More particularly, this invention relates to a method and apparatus for recording on a recording medium using a helical scan track write/read technique with a serpentine track pattern to increase the data capacity toward one Terabyte. Still more particularly, this invention relates to a linear sliding scanner with a read/write head stack for performing the helical scan serpentine recording and a method for using the same. Finally, this invention relates to a UFB offset spool cartridge for operatively housing the UFB format recording medium according to the present invention, and a method for loading the same into a tape drive apparatus. 
   2. Brief Discussion of the Related Art 
   Currently-available high density recording technology provides high-density, large capacity recording in 8 mm cartridges that are much smaller than other data cartridge formats. AIT cartridges are available that feature a built-in flash memory chip, such as a remote, non-contact, Memory in Cassette (“MIC”) system, for providing key information directed to a drive for the cartridge. Prior efforts by the assignees of this invention have expanded use of the AIT cartridge with the MIC chip to improve reliability, error prediction, and performance in recording and retrieving data on partitioned tape. An example of the use of MIC technology is shown in U.S. Pat. No. 6,611,394. Associated MIC hardware includes a multi-pin interface to the drive or other external connection to store and retrieve selected information directly from the chip to provide real time customer applications. 
   MIC information consists of data written at the time of cartridge manufacture when the media is first loaded into an AIT drive, portions of the media updated as a part of a recording sequence, and portions of the media that can be written directly by a user&#39;s application. A net result is improved access to data when used in conjunction with tape partitioning, reducing, for example, access time up to 50 percent as compared to conventional methods. U.S. Pat. No. 6,674,596, U.S. Pat. No. 6,624,959, and U.S. Pat. No. 6,301,067 are examples of the use of a solid-state memory control of partitioned tape so that it is not necessary to rewind a tape to the beginning when it is desired to record new data. 
   A current version of AIT cartridges, known as the AIT-3 (a trademark of Sony) is able to hold 100 GB native and up to 260 GB of compressed data, due in part to a use of helical scan recording technology. 
   Advanced Metal Evaporated (“AME”) is a tape formulation used in AIT installations. Its key characteristics include a 100% pure cobalt magnetic layer design, the absence of binder material to prevent tape head contamination, and a Diamond Like Carbon (“DLC”) protective coating for extreme durability. AME also permits very high-density magnetic recording, thereby allowing the AIT family roadmap to reach large capacity levels. 
   It remains, however, an overall aim in the art to improve recording capability, such as from 100 GB to a target of 1 Terabyte, a 10 fold increase, building on the technology discussed above, and to increase the speed of access and retrieval of data. 
   Efforts are known that propose the use of serpentine recording patterns, such as in the multi-track recording technique discussed in U.S. Pat. No. 6,154,334 to Pine, as a time-saving traversal pattern. However, that serpentine traverse has not been previously used in conjunction with helical scanning techniques on flexible recording media. 
   It is an additional problem in this technology to provide a helical scan recording/playback device capable of achieving a serpentine traverse of the recording media, particularly when the recording media is a flexible media such as a recording tape. 
   SUMMARY OF THE INVENTION 
   Directed to achieving the foregoing objectives of the invention, and improving a data cartridge according to the prior art, this invention relates to a recording medium, such as an elongated tape and preferably an AME tape, for a cartridge, preferably an AIT cartridge. The recording medium has a plurality of elongated tracks parallel to a center track of the medium on opposite sides wherein the tracks are respectively odd and even numbered. In the tape, a plurality of partitions are formed so that a retrievable address for stored data can be easily located, preferably by use of an MIC chip. Recorded data on the tape is recorded by a helical scan on a track in a serpentine fashion, i.e. a scan of a “0” track in a first direction from the beginning of the tape to the end of the tape, a scan of a “1” track in an opposite direction, a scan of a “2” track again in the first direction, a scan of a “3” track again in the opposite direction, and so forth. 
   A feature of the invention relates to a linear scanning member supporting at least one recording/playback head stack, with a scanner/drum assembly for achieving the helical scan and serpentine recorded configurations on the tape. The linear sliding scanner is best seen in  FIGS. 3 ,  4  and  5 , while the recording function is shown in  FIGS. 2A ,  2 B, and  2 C utilizing the linear sliding scanner for recording on the tape. 
   Another feature of the invention relates to a recording/playback recording medium, comprising an elongated, flexible recording/playback medium having a predetermined width and a predetermined length, together defining a recording/playback area capable of providing a plurality of elongated recording/playback tracks. Information is located on at least two tracks, a first track being recorded from the beginning of the first track in a first direction until the track is filled, the second track being recorded in a second opposite direction, the tracks being partitioned to define sectors having identifiable locations. The first, second, and subsequent tracks if necessary are recorded in a serpentine manner, and the information recorded on the tracks is recorded by a scanner/drum assembly using a helical scan technique. 
   The first track is located at about the longitudinal center of the flexible medium, the second track is located toward a first odd side of the first track, a third track is located on a side opposite the first track toward a second even side of the first track, and so forth for a total number of tracks in the area. A remote MIC chip is provided for identifying sectors on the flexible medium for addressing data for recording and/or playback. 
   According to another feature of the invention, means are provided for recording on selected tracks of the medium, the recording means including a recording/playback head stack and means for incrementing the head stack relative to a preselected recording track on the flexible recording medium. Means are also provided for recording/playback of helical scan signals on the preselected recording track. Still further, means capable of recording/playback on any track between edges of the flexible recording medium are also provided 
   Another feature of the invention relates to a linear sliding apparatus and a scanner/drum assembly, the linear sliding apparatus being capable of linearly sliding transversely relative to the flexible recording medium. The scanner/drum assembly is capable of helical recording on a preselected track. A first motive means for incrementing the scanner/drum assembly relative to the preselected track, and a second motive means are included for driving the scanner/drum assembly for recording and/or playback. 
   Another feature of the invention relates to a method of recording information on a recording/playback medium, comprising the steps of providing an elongated flexible recording/playback medium having a predetermined width and a predetermined length together defining a recording/playback area having a plurality of tracks; recording information on at least two tracks in the area, including the steps of recording on a first track from a beginning of the tape end to an end of the tape in a first direction, and recording on a second track from an end of the tape toward the beginning of the tape in a second, opposite direction, the tracks being partitioned to define sectors having identifiable locations. The recording/playback further includes a step of helical scan recording on preselected tracks. Still further, the method includes a step of selecting an address of the identifiable locations using a remote MIC chip. Another feature of the method includes additional steps of helical scan recording in an additional plurality of tracks on the flexible recording medium in a serpentine manner. 
   Another feature of the present invention relates to an apparatus for helical scan recording/playback from preselected tacks on a flexible tape medium, comprising a linear slide structure capable of movement transversely relative to a longitudinal direction of the tape medium, the linear slide structure including a scanner/drum capable of sliding movement relative to a longitudinal direction of the tape medium between opposed edges of the tape medium defining a recording area, the scanner/drum having a head stack for helical scan recording/playback of the preselected tracks; and a stepper motor on a trolley end of the linear slide structure for causing the scanner/drum to slide transversely relative to the longitudinal direction of the tape medium. 
   The linear slide is preferably structured so that the scanner/drum is able to traverse the tape medium longitudinally between the opposed edges. In addition, the head stack of the scanner/drum preferably scans the tape medium housed in a UFB cartridge having main tape guides that lock upon loading into main tape guide locators provided in the base of the linear slide structure; and the UFB cartridge further includes slant tape guides for guiding the tape between spools that are offset to compensate for a helical scan wrap angle in the UFB cartridge. The UFB cartridge may also include a remote MIC located in an upper portion of the UFB cartridge adapted to store address locations of files on the tape medium. This MIC may also store data for operation in an AIT format 
   Another feature relates to a method of using a linear slide scanner to perform helical scan serpentine recording/playback of select tacks on a flexible tape medium, comprising the steps of bringing a scanner/drum assembly of the linear sliding scanner device into contact with the flexible tape medium; advancing the flexible tape medium in either a forward or a reverse direction; advancing the linear sliding scanner in a linear direction transverse to the direction of travel of the flexible tape medium; and rotating a recording/playback head stack of the scanner/drum assembly to perform, in conjunction with the forward or reverse direction of travel of the flexible tape medium and the linear movement of the linear sliding scanner, helical scan serpentine recording/playback of the select tracks of the flexible tape medium. This method may additionally include a step of selecting an address of the select tracks using a remote MIC chip. 
   According to this method, the linear sliding scanner is preferably advanced in the linear direction via a stepper motor and the recording/playback head stack is rotated via a scanner motor. The stepper motor and the scanner motor are additionally preferably controlled by a tracking servo. 
   Yet another feature of the invention relates to a cartridge for operatively housing a recording/playback medium, comprising a first spool and a second spool located at offset positions inside a cartridge shell body; a recording/playback medium of a fixed width and length wound around the first and second spools; and a plurality of slant tape guides positioned between the first and second spools for guiding the recording/playback medium and for creating a helical scan tape wrap angle in connection with a plurality of main tape guides, the plurality of main tape guides being positioned between the first and second spools; wherein the cartridge shell body comprises: a plurality of pull out arm assemblies serving as enclosure doors for a bottom surface of the cartridge shell body, the pull out arm assemblies further serving as semicircular side walls of the cartridge shell body; a top plate; and opposing end plates formed perpendicular to the pull out arm assemblies and the top plate. 
   Preferably, semicircular portions of the pull out arm assemblies are formed around the spools so as to be rotatable, such that when the semicircular portions of the pull out arm assemblies are rotated around the spools, flat portions of the pull out arm assemblies serving as the bottom surface of the cartridge shell body rotate to expose the recording/playback medium. A shutter is additionally preferably formed in a bottom portion of each opposing end plate, the top portion of the shutter being hingedly attached to each opposing end plate so as to be pivotably opened to define an opening in each opposing end plate slightly larger in width than a width of a linear sliding scanner device used for helical scan recording/playback of the recording/playback medium. 
   Circular spool hubs are formed on one end of each spool so as to be accessible via an opening defined in one of the opposing end plates, the spool hubs containing receiving portions for receiving drive reel tables of a recording/playback apparatus for transversely advancing the recording/playback medium in a forward and a reverse direction. 
   A remote MIC is additionally preferably located within the cartridge shell body for identifying sectors on the recording/playback medium for recording and/or playback. 
   Main tape guides and slant tape guides are preferably formed internally within the cartridge shell body. 
   Yet another feature of the invention relates to a method for performing a loading and a recording/playback operation on a cartridge operatively housing a recording/playback medium, comprising the steps of inserting the cartridge into a tape drive apparatus; rotating pull out arm assemblies serving as a bottom surface of the cartridge via a first motive means contained within the tape drive apparatus, thereby exposing a recording/playback medium wrapped around a pair of spools enclosed within the cartridge; pivotably opening shutters formed in a bottom portion of opposing end plates of the cartridge via a second motive means contained within the tape drive apparatus to define an opening in each opposing end plate slightly larger in width than a width of a linear sliding scanner device used for recording/playback of select tracks of the recording/playback medium; after the pull out arm assemblies have rotated fully and the shutters have opened fully, inserting and locking a plurality of main tape guides located within the cartridge into a corresponding plurality of main tape guide locators provided in a base portion of the linear sliding scanner device via a third motive means contained within the tape drive apparatus, the plurality of main tape guides used in conjunction with a plurality of slant tape guides and a pair of spools to create a helical scan tape wrap angle for helical scanning of the recording/playback medium; and bringing a scanner/drum assembly of the linear sliding scanner device into contact with the exposed recording/playback medium via the third motive means to allow the scanner/drum assembly to perform helical scan recording/playback of the select tracks of the recording/playback medium. 
   This method additionally preferably provides steps for transversely advancing the recording/playback medium via a tape drive motor provided in the tape drive apparatus and attached to drive reel tables inserted into spool hubs of the spools in either a forward or a reverse direction; advancing the linear sliding scanner device via a stepper motor in a linear direction transverse to the direction of travel of the recording/playback medium; and rotating a recording/playback head stack of the scanner/drum assembly via a scanner motor to perform, in conjunction with the linear movement of the linear sliding scanner device, helical scan serpentine recording/playback of the select tracks of the recording/playback medium. A remote MIC chip located within the cartridge may also preferably be used to identify sectors on the recording/playback medium for recording and/or playback. The tape drive motor, stepper motor, and scanner motor may also be controlled by a tracking servo. 
   These and other features of the invention will become more apparent from a review of the detailed description of the drawings and the written description that follow. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a plan view of a tape showing the helical scan pattern on each longitudinal track, and a serpentine pattern for a plurality of tracks, according to the invention. 
       FIG. 2  is a top view of a scanner for recording/playback of the tape of  FIG. 1 , wherein  FIG. 2A  is a first longitudinal scan at a track position “ 0 ”;  FIG. 2B  is a depiction of a longitudinal scan at a maximum odd position near a first side of the tape; and  FIG. 2C  is a depiction of a longitudinal scan at a maximum even position near a second, opposite side of the tape. 
       FIG. 3  is a top view of a linear slide device with a scanner/drum assembly for achieving the recording/playback patterns shown in  FIGS. 1 and 2 . 
       FIG. 4  is a side view of the linear slide device and scanner/drum assembly of  FIG. 3  showing a tape guide datum position. 
       FIG. 5  is an enlarged end view of the linear slide device of  FIG. 3  showing in diagrammatic form the essential components of the structure for achieving the linear sliding needed for both helical scanning and serpentine tracking. 
       FIG. 6A  is a top view of a UFB offset spool cartridge concept for housing the helical serpentine scanned tape according to the present invention; and  FIG. 6B  is a bottom view of the spool cartridge. 
       FIG. 7A  is a diagrammatic end view of the UFB offset spool cartridge of  FIGS. 6A–6B  showing the essential components of the spool cartridge needed for housing and guiding the tape according to the present invention;  FIG. 7B  is a front end view of the UFB offset spool cartridge of  FIGS. 6A–6B ; and  FIG. 7C  is a rear end view of the UFB offset spool cartridge of  FIGS. 6A–6B . 
       FIG. 8  is a diagrammatic top view of the UFB offset spool cartridge showing its shutter closed and positioned above the linear scanning assembly of  FIG. 5 . 
       FIG. 9  is a diagrammatic top view of the UFB offset spool cartridge showing its shutter open to receive the linear scanning assembly of  FIG. 5  for recording/playback of the tape. 
   

   DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1  shows a recording/playback format on a tape, shown generally by the reference numeral  10 , to provide a continuing alternating serpentine pattern for a plurality of recording tracks  12  suitable for helical scan recording/playback. This format was developed as a fast access data storage system that may be used for any data storage application using a recording medium such as a tape, CD, or disc. The UFB format, shown generally in  FIG. 1 , thus utilizes “helical scan” track write/read principles combined with a “serpentine” track pattern. Thus, the relatively short length of the tape and the novel Linear Sliding Scanner drive arrangement, shown in  FIGS. 2 to 5 , enables fast access to any physical location on the recording/playback media, such as the tape  10 . For example, the tape  10  may be separated into a plurality of recording tracks  12  longitudinally adjacent one another, identified for access by, for example, use of a remote, or non-contact MIC chip to allow for file location and cartridge history information to be accessed quickly. 
   The tape  10  in  FIG. 1  has a length  16  extending between a beginning of tape (“BOT”) end  18 , and an end of tape (“EOT”) end  20 . For convenience, the length  16  will be considered the effective recordable length, recognizing that the BOT end  18  and the EOT end  20  may also include tape lead and tape exit sections (not shown). The tape width  22  is defined transversely by an odd side edge  19  and an even side edge  21 . For convenience, the odd side edge  19  is at an odd track side of the longitudinal center  25  of the tape, while the even side edge  21  is at an even track side of the longitudinal center of the tape. 
   A first recording track  24  is at the longitudinal center  25  of the tape  10 . A plurality of tracks, denominated “Track  01 ”, “Track  03 ” and so forth are on the odd track side of the tape  10  between the longitudinal center  25  of the tape and the odd side edge  19  of the tape. A “Max Odd Track”  26  is located adjacent the odd side edge  19  of the tape at a convenient distance to permit recording in the track without traversing the odd side edge  19  during recording/playback. 
   Similarly, a plurality of even tracks, denominated “Track  02 ” and so forth, are located between the longitudinal center  25  of the tape  10  and the even side edge  21 . A “Max Even Track”  27  is located adjacent the even side edge  21  at a convenient distance to permit recording with traversing the even side edge  21 . 
   A typical tape  10  has a preferable length of 100 meters, with a 12.75 cm. wide media and with a plurality of 6 mm. wide recording track bands, thus to provide a target data capacity of 1 Terabyte, at least a 10 fold increase of recording capacity for a tape of the type contemplated. It may be noted, however, that the track width and the total number of tracks are not fixed at this time, so that the representative numbers stated are those currently contemplated. 
   The longitudinally extending recording tracks  12  are recorded using helical scan techniques, well known to the art of recording and digital recording. A serpentine recording pattern is preferred, so that a novel combination of “helical scan” and “serpentine” track patterns is utilized. Preferably, the serpentine track pattern begins at Track  0  at the longitudinal center of the tape  10  at its BOT end, along a right-to-left direction until the EOT end is reached. As the recording approaches the EOT end, recording will stop, and the tape  10  will reverse direction and the linear sliding scanner  30  containing the recording/playback head stack  39  will shift a distance of one track toward the odd side edge  19 , thus to permit another track, e.g. Track  01 , to be recorded with a helical signal. Recording of Track  01  will be in a direction that is a reverse of Track  0 , i.e. from the EOT end to the BOT end. Upon approaching the BOT end, the linear sliding scanner  30  will shift toward the rear of the drive that is toward the even side edge  21 , to allow another band of tracks to be recorded. The process described may continue until the usable surface of the media is fully utilized, as shown in  FIG. 1 . Thus, as demonstrated in  FIGS. 2A–2C , the linear sliding scanner  30  is able to linearly traverse among positions ranging from the maximum odd position near a first side of the tape, shown in  FIG. 2B , to the maximum even position near a second, opposite side of the tape  10 , show in  FIG. 2C . 
   If recording is complete at a position intermediate the ends of the tape, at an identified sector, when recording is resumed, it will be located at a position adjacent the identified sector, and in a direction that was in process at the time recording was terminated. For example, a recording of Track  02  may terminate at a position such as Track  02 A (not shown) formed while recording in a right to left matter, i.e. from the BOT end to the EOT end. When recording resumes, the recording of Track  02  may continue in the same right to left manner from the same position, i.e. Track  02 A. 
   Another feature of the present invention relates to a linear sliding scanner  30 , capable of sliding beneath the tape  10 , and supporting at least one recording/playback head stack  39  with a scanner/drum assembly  40  for achieving the helical scan, serpentine recorded configurations described above on the tape  10 . The linear sliding scanner  30  is best seen in  FIGS. 3 ,  4  and  5 , while the recording function is shown in  FIGS. 2A ,  2 B, and  2 C utilizing the linear sliding scanner  30  for recording on the tape  10 . 
   Turning first to the structure of the linear sliding scanner  30 , seen in  FIGS. 3–5 , this scanner  30  includes a casing having a right side wall  31  and an opposed left side wall  32 , respectively closed at their ends by end members  33  and  34 . The casing as described defines a linear slide distance  42  intermediate its ends  33 ,  34 , to permit the scanner/drum assembly  40  with its recording/playback head stack  39  to traverse among a first location shown in  FIG. 2A , and respective locations shown in  FIGS. 2B and 2C , to perform recording on the tape or flexible media. The linear sliding scanner  30  and the scanner/drum assembly  40  are preferably formed to have approximately 28 cm. of media contact length. 
   The scanner/drum assembly  40  of the linear sliding scanner  30  as shown in  FIG. 3  is responsive to a stepper motor  35  for causing the scanner/drum  40  and stack head  39  to respectively traverse selected tracks in the serpentine pattern described. The stepper motor  35 , which is in operative rotatable connection with the base of the linear sliding scanner  30  via bearings  43 , drives a lead screw  36  connected to an end trolley  37 , while another opposed end trolley  41  is connected to the lead screw  36  at the opposed end mating with the end member  33 . The stepper motor  35  is controlled by a tracking servo (not shown) cooperating with an MIC chip to determine stepping locations for the head stack  39  relative to the tape  10 , as generally seen in  FIGS. 2A ,  2 B, and  2 C. Tape guide datums  45  are additionally provided in the base unit of the linear slide scanner  30  to help in guiding and positioning the tape  10  during recording/playback. 
   By the use of the stepper motor  35 , the head stack  39  is positioned relative to a selected track on the tape  10 , and its location is verified by the use of a memory cooperating with the MIC chip. When the head stack  39  is appropriately positioned relative to a selected track by the stepper motor  35  in the above-described manner, helical scanning occurs in that track to the extent the track is traversed generally orthogonally relative to the linear sliding scanner  30 . Thus, as best seen in  FIGS. 4 and 5 , the stepper motor  35  results in causing the scanner/drum  40  to move transversely relative to the tape  10  for helical scan recording. 
   More specifically, the linear sliding scanner  30  has an ability to transversely slide beneath the tape  10 , allowing the tape  10  to freely pass above the scanner/drum assembly  40  during the helical scan. To that end, air may be injected through the drum surface to provide an air film to assist in media movement over the scanner/drum assembly  40  and head stack  39 . 
   Once the head stack  39  has been appropriately positioned relative to a selected track by the stepper motor  35  in the above-described manner, a scanner motor  38  initiates helical scanning of the recording/playback head stack  39 . A feature of the invention is that, to control eccentricity of the drum unit  40 , only the recording/playback head stack  39  is caused to rotate. As described above, air may be injected through the drum surface to provide an air film to assist in media movement over the rotating head stack  39 . 
   Together, the lead screws  36 , end trolleys  37 ,  41 , and the scanner/drum  40  with the recording/playback head stack  39  responsive to the stepper motor  35  and scanner motor  38  define a linear sliding scanner  30  for accurately traversing the tape  10  for incremental, serpentine helical recording and/or playback as has been described. 
   A UFB offset spool cartridge concept will now be described with reference to  FIGS. 6A–6B ,  7 A– 7 C and  8 . As seen in  FIG. 6A , a UFB spool cartridge  50  includes a cartridge shell body  52  having openings for housing and mounting a spool  55  at a location  61 , and for housing and mounting a spool  56  at a location  62 . The cartridge shell body  52  is defined by a top plate  70 , two pull out arm assemblies  71 ,  72  serving as enclosure doors for a bottom surface of the spool cartridge  50  and further serving as semicircular right and left side walls, respectively closed at their ends by opposing end plates  57 . When the spool cartridge  50  is in a closed shutter position  82 , as demonstrated in previous  FIG. 6B , the edges of the pull out arm assemblies  71 ,  72  meet at approximately the longitudinal center of the cartridge shell body  52  to effectively form the bottom surface of the cartridge shell body  52 . However, when the spool cartridge  50  is in an open shutter position  84 , as shown in  FIG. 9 , the pull out arm assemblies  71 ,  72  rotate around the spools  55 ,  56 , respectively, to expose the tape  10  to the linear sliding scanner  30  for helical scanning. 
   Slant guides  66  and  68  are internally provided in the cartridge body  52  for guiding the tape  10  through a helical scan tape wrap angle, shown in  FIG. 6A , relative to internally-provided main tape guides  67  and  69 . In fact, the UFB spool cartridge  50  is preferably designed so as to incorporate all tape guides internally, thereby simplifying the overall design of the spool cartridge  50 . 
   In addition, as best seen in the top view of  FIG. 6A , the spools  55  and  56  are offset from one another to compensate for the helical scan tape wrap angle created by the slant guides  66 ,  68  and main tape guides  67 ,  69 . A remote or non-contact MIC chip  78  is attached to the bottom surface of the top plate  70  of the cartridge shell body  52  for identifying and/or locating sectors on the tape  10  for recording and/or playback in the previously-described helical serpentine manner. 
   As seen in  FIG. 7C , exposed spool hubs  80 ,  81  of the spools  55 ,  56 , respectively, are provided in the rear end plate of the cartridge shell body  52 . When the UFB spool cartridge  50  is loaded into a UFB recording/playback apparatus (not shown) for recording and/or playback, drive reel tables (not shown) of the UFB recording/playback apparatus are inserted into the exposed spool hubs  80 ,  81  and are controlled by a tracking servo (not shown) to drive the spool hubs  80 ,  81  and the spools  55 ,  56  connected thereto in a clockwise or counter-clockwise manner, thereby rotationally advancing the tape  10  in either a forward direction (from the BOT  18  to the EOT  20 ) or a reverse direction (from the EOT  20  to the BOT  18 ). Driving the tape  10  via the drive reel tables in this manner eliminates the need for conventional capstan and pinch roller assemblies, further simplifying the overall design of the offset cartridge  50 . 
   Shutters  63 ,  64 , seen in  FIGS. 6A–6B ,  7 B– 7 C,  8  and  9 , being slightly larger in width than that of the linear sliding scanner  30 , are provided in the bottom center portion of each end plate  57 . These shutters  63 ,  64  are fastened to the end plates  57  in any number of ways conventional in the art of fastening, including via elastomeric means, hinge means, etc. When the shutters  63 ,  64  are in a closed shutter position  82 , as seen in  FIG. 8 , the shutters  63 ,  64  function to continuously form a portion of each end plate  57 . However, when the shutters  63 ,  64  are brought into an open position during an opening/loading operation, seen in  FIG. 9 , an opening in the end plates  63 ,  64  slightly larger in width than that of the linear sliding scanner  30  is defined, thereby allowing the body of the linear sliding scanner  30  to be inserted inside the body of the UFB spool cartridge  50 . 
   An opening/loading operation of the spool cartridge  50  will now be described with reference to  FIGS. 8–9 . Once the UFB spool cartridge  50  has been inserted into a UFB recording/playback apparatus (not shown), a drive motor apparatus (not shown) within the UFB recording/playback apparatus brings loading arms of the apparatus (not shown) into operative contact with the pull out arm assemblies  71 ,  72  and the shutters  63 ,  64  of the spool cartridge  50 . Once in operative contact, the loading arms are driven by the drive motor of the recording/playback apparatus to pull open the pull out arm assemblies  71 ,  72  and to pivotably open the shutters  63 ,  64  of the spool cartridge  50 . It should be noted that the UFB spool cartridge of the present invention has been designed to be compatible with conventional recording/playback apparatuses, including, in particular, conventional AIT tape drive apparatuses. 
   After the pull out arm assemblies  71 ,  72  and the shutters  63 ,  64  have been fully opened, thereby exposing the tape  10 , the linear sliding scanner  30  is moved toward the interior of the spool cartridge  50  via the drive motor within the UFB recording/playback apparatus until the main tape guides  67 ,  69  of the spool cartridge  50  are inserted and lock into main guide locators  73 ,  75  provided in the base of the linear sliding scanner  30 . Such a loading operation brings the head stack  39  of the scanner/drum assembly  40  into direct proximity with the exposed tape  10 , such that the tape  10  now traverses between spool  55  and spool  56  in an irregular path defined in part by the spool  55 , the slant guide  66 , the main tape guide  67 , the scanner/drum assembly  40 , the main tape guide  69 , the slant guide  68 , and the spool  56 . 
   Once the UFB spool cartridge  50  has been loaded into the UFB recording/playback apparatus, the pull out arm assemblies  71 ,  72  and shutters  63 ,  64  of the spool cartridge body  52  have been fully opened, and the main tape guides  67 ,  69  of the spool cartridge  50  have been inserted and locked into the main guide locators  73 ,  75  of the linear sliding scanner  30 , thereby bringing the scanner/drum assembly  40  of the linear sliding scanner  30  into contact with the tape  10 , a recording/playback operation may begin in the helical serpentine manner described earlier. 
   Although the principles and modes of operation of this invention have been explained and illustrated in preferred embodiments, in accordance with the provisions of the patent statutes, it must be understood that this invention may be practiced otherwise than is specifically explained and illustrated without departing from its spirit or scope.