Abstract: A tape head including a body with a tape-bearing surface configured to contact a magnetic tape, at least one transducer that is a read or write element, configured so the tape head may read from or write to the tape, in operation; and a monobloc closure with a structured cross-sectional profile, so as to exhibit: contact part, fixed on a side of the body which adjoins the tape-bearing surface at an edge thereof, the contact part having a top surface level with the tape-bearing surface; and connecting part integral with the contact part, the connecting part having a top surface recessed from the contact part's top surface, perpendicularly to a contact plane defined by the tape-bearing surface, so the connecting part's top surface does not contact the tape, in operation; and a broken line of mechanical weakness that extends at an end of the top surface of the connecting part.

Abstract: A differential amplifier includes an input common mode voltage generation unit suitable for generating an input common mode voltage, an input common mode voltage sampling unit suitable for performing an independent sampling operation on the input common mode voltage, and a differential amplifying unit suitable for performing a differential amplifying operation on an input voltage and the sampled input common mode voltage.

Abstract: A method of manufacturing a drum assembly associated with a digital betacam video tape machine is disclosed. The method includes providing a helical scan drum assembly having a stationary upper drum, a stationary lower drum and a plurality of rotating read/write heads disposed between the stationary upper and lower drums. The rotating read/write heads reading and writing digital information to and from a tape. The method further includes inserting air grooves in the outer peripheral surface of the upper drum. The air grooves are configured to reduce sticktion between the tape and the outer peripheral surface of the upper drum when the tape is moved around the outer peripheral surface of the upper drum. The method additional includes mounting an adjustable band to the outer peripheral surface of the lower drum. The adjustable band is configured to guide the tape around the drum assembly in accordance with helical scans when the tape is moved around the outer peripheral surface of the upper drum.

Abstract: A magnetic head comprises an MR element, and a substrate supporting the MR element from both sides at a center portion, and a magnetic tape is in contact and slide-contact with a slide-contact surface thereof. A curvature in a thickness direction of the slide-contact surface is set to be larger at a center portion than at both sides thereof. In this way, it is possible to protect the slide-contact surface of the magnetic head from eccentric wear and avoid deterioration of the magnetic head performance.

Abstract: A rotary drum includes a plurality of reproducing heads each having a plus azimuth angle (+azimuth angle), which heads are collectively arranged at a location in the circumferential direction of the rotary drum in such a manner as to be in close proximity to each other, to be taken as a +azimuth reproducing head group, and a plurality of reproducing heads each having a minus azimuth angle (?azimuth angle), which heads are collectively arranged at a location in the circumferential direction of the rotary drum in such a manner as to be in close proximity to each other, to be taken as a ?azimuth reproducing head group, wherein the +azimuth reproducing head group and the ?azimuth reproducing head group are spaced from each other in the circumferential direction of the rotary drum. With this rotary drum, signals can be certainly reproduced from recording tracks with narrowed widths by using the multiple reproducing heads arranged on the rotary drum.

Abstract: Disclosed herein is a rotary head drum unit including a cylindrical drum surface and a magnetic head for recording/reproducing a signal to/from a magnetic tape running along the drum surface. The magnetic head has a tape sliding surface adapted to come into sliding contact with the magnetic tape. The tape sliding surface of the magnetic head is positioned at a level lower than the height of the magnetic tape flying above the drum surface. The magnetic tape is brought into contact with the tape sliding surface by negative pressure. With this configuration, an increase in contact pressure of the magnetic tape sliding on the tape sliding surface of the magnetic head can be prevented and the contact pressure can be uniformed to thereby prevent a reduction and variations in magnetic recording or reproduction output.

Abstract: In a video recorder with a rotary head drum, a lower drum (1) and drum base (2) are joined together by laser welding to simplify assembly and reduce manufacturing cost.

Abstract: A magnetic recording apparatus includes first magnetic recording elements and second magnetic recording elements. The first magnetic recording elements precede the second magnetic recording elements. The second magnetic elements record signals to form second signal tracks between wide signal tracks previously formed by the first magnetic recording elements by recording signals so that the second signal tracks partly overlap the first signal tracks on both sides of the second signal tracks.

Abstract: A magnetic recording/reproducing apparatus includes first magnetic heads including at least two magnetic reproducing elements disposed at a first azimuth angle, and second magnetic heads including at least two magnetic reproducing elements disposed at a second azimuth angle. The first and second magnetic heads are mounted to a rotating drum. The magnetic reproducing elements of the magnetic heads scan at the same time recording tracks formed by recording signals at the same azimuth angle, with an odd number of at least three recording tracks being disposed between the recording tracks that are scanned.

Abstract: There is provided a rotary magnetic head including a pair of magnetic heads where a difference in voltages of output signals therebetween is made small by arranging the structure thereof such that azimuth angles of gaps of the magnetic heads are different from each other; heights of the magnetic heads from the corresponding gaps to corresponding board surfaces are set equal to each other; each of the magnetic heads is formed by mutually abutting I-type and C-type cores; the gaps lie closer to one side with respect to the width direction of the I-type and C-type cores; and, in the rotating direction of a rotating cylinder, the C-type core of one of the magnetic heads moves ahead of the I-type core of the same and the I-type core of the other magnetic head moves ahead of the C-type core of the same.

Abstract: In a head drum assembly mounting structure on a deck of a tape recorder, a plurality of connecting holes and positioning holes are formed in a drum boss provided at a lower portion of a fixing drum, and a plurality of coupling holes and positioning pins are formed in a drum base which is slant disposed on a main base. By using the positioning holes and the positioning pins as positioning means which are connected to each other in complementary fashion, the coupling holes of the drum base and the connecting holes of the drum boss are aligned with each other, and by fastening a screw into such aligned coupling holes and the connecting holes, the head drum assembly can be directly coupled to the main base while being slant disposed with respect to the main base. Accordingly, any possible damage to a lead line is prevented, and assembly efficiency is improved, while the number of parts and the manufacturing cost are reduced.

Abstract: In a rotary magnetic head, two pairs of video head core bars for Rch and Lch (R1, L2, R2, L1) forming a gap are fabricated, and the video core bars are arranged face up and back (R1 and R2 are faced, L2 and L1 are back). The direction of each gap is inclined by 6 degrees to a direction perpendicular to the slice line, and the reference height position of the gap of 2nd bar is set higher by a specified amount from the reference height position of the gap of 1st bar, and is fixed. By cutting out the video core bars simultaneously, two pairs of head cores optimized in the height of the reference position of the gap from the cutting-out surface are formed. By adhering the cutting-out surfaces of the head cores to a common base, the cores are positioned at a desired height, and core height adjusting mechanism is not needed.

Abstract: A thin film magnetic head includes a head element portion stacked on a side surface of a substrate having two opposed planes, two opposed side surfaces intersecting the planes, and a tape slide surface provided at one end portion of the planes and the side surfaces. At least one of a magnetic gap Gb of an induction type magnetic head and a magneto-resistive effect element Ga of a magneto-resistive effect type magnetic head are exposed on the tape slide surface, and a bonding pad 3 is connected to the head element portion, wherein an angle made by one of the side surfaces on which the head element portion and the bonding pad are provided and one of the planes constitutes an azimuth angle.

Abstract: A magnetic head, a recording and/or playback method for a tape-type magnetic recording medium and a rotary magnetic head mechanism which are simple in structure and superior in contact characteristic with a tape-type magnetic recording medium. A window portion is formed in a concave manner on an outer circumferential face of a rotary drum along which a magnetic tape can be wrapped. A flat head of a width smaller than that of the window portion in the advancing direction is disposed in the window portion such that a pair of channels each in the form of an air gap are formed between the opposite leading and trailing ends of the flat head and the opposite leading and trailing ends of the window portion, respectively. The flat head has an exposed smooth flat face extending perpendicularly to a diametrical direction of the rotary drum and provided at a position retracted from the outer circumferential face of the rotary drum for being opposed to and fluidically interference with the magnetic tape.

Abstract: A magnetic head mounted on a rotary head drum device comprises a head chip, and a magnetic shield disposed to surround all or a part of surfaces other than a front surface of the head chip. The magnetic shield comprises a magnetic flux absorber made of ferrite and an electromagnetic wave shield made of copper. This enables reduction of the amount of unnecessary magnetic fluxes and electromagnetic waves jumping away from the recording head to the reproducing head. Simultaneously, the magnetic flux absorber absorbs the magnetic flux coming from outside to the reproducing head before the magnetic flux reaches the head chip and the electromagnetic wave shield shields a high frequency electromagnetic wave which was not absorbed by the magnetic flux absorber so that it is possible to reduce the amount of the magnetic flux or the like jumping into the reproducing head and to improve the S/N of the reproduced signal.

Abstract: In processing a head unit in which a head relative height Y is Y′ with a grinding amount &Dgr;GD of &Dgr;GD′, the relationship between distances Bo between a vertex of a curved surface as a front face of a head chip and a head gap before and after grinding the front face of the head chip and a gap depth dimension GD, is predetermined with respect to a head unit in which the head relative height is substantially equal to Y′, through which Bo1 as the value of Bo before grinding corresponding to a target value of the value of Bo after grinding is determined and used as Bo1 of the head unit in which the head relative height Y is Y′. Thus, grinding of the front face of the head chip is conducted after Bo1 corresponding to the target value is determined. Hence, a head unit with the value of Bo after grinding falling within the range of standard values can be manufactured efficiently, and accordingly the yield can be improved.

Abstract: Disclosed herein is a rotary head drum unit including a cylindrical drum surface and a magnetic head for recording/reproducing a signal to/from a magnetic tape running along the drum surface.. The magnetic head has a tape sliding surface adapted to come into sliding contact with the magnetic tape. The tape sliding surface of the magnetic head is positioned at a level lower than the height of the magnetic tape flying above the drum surface. The magnetic tape is brought into contact with the tape sliding surface by negative pressure. With this configuration, an increase in contact pressure of the magnetic tape sliding on the tape sliding surface of the magnetic head can be prevented and the contact pressure can be uniformed to thereby prevent a reduction and variations in magnetic recording or reproduction output.

Abstract: The present invention provides a rotary head comprising a tubular rotary cylinder; and a magnetic head for carrying out at least one of recording and reading of information with respect to a magnetic tape transported about the rotary cylinder; wherein the magnetic head is supported so as to be movable toward the outside of the rotary cylinder.

Abstract: A helical-scan system performs recording and reproduction on a magnetic tape by using a recording and reproducing head 5 comprising m magnetic head elements 7 (where m is 2 or larger integer). During this recording and reproduction, the following relationships are satisfied among a track width W for each of the head elements 7, a track pitch Tp between the head elements 7, and a feed amount S for a magnetic tape 6.

Abstract: A rotary drum includes a plurality of reproducing heads each having a plus azimuth angle (+azimuth angle), which heads are collectively arranged at a location in the circumferential direction of the rotary drum in such a manner as to be in close proximity to each other, to be taken as a +azimuth reproducing head group, and a plurality of reproducing heads each having a minus azimuth angle (−azimuth angle), which heads are collectively arranged at a location in the circumferential direction of the rotary drum in such a manner as to be in close proximity to each other, to be taken as a −azimuth reproducing head group, wherein the +azimuth reproducing head group and the −azimuth reproducing head group are spaced from each other in the circumferential direction of the rotary drum. With this rotary drum, signals can be certainly reproduced from recording tracks with narrowed widths by using the multiple reproducing heads arranged on the rotary drum.

Abstract: To provide a magnetic head, a recording/reproducing method for a tape magnetic recording medium and a rotary magnetic head mechanism. A flat head FH1 is mounted on a rotary drum DR1 capable of allowing a magnetic tape MT to run thereon, and a smooth flat surface PL1 that faces the magnetic tape MT and produces hydrodynamic interference with the magnetic tape MT is provided on a flat head FH1, and a head element HE1 that contacts the magnetic tape MT and produces magnetic interference is provided in the area where the magnetic tape MT contacts the smooth flat surface PL1.

Abstract: A rotary head assembly including a plurality of magnetic heads with predetermined azimuth angles. These magnetic heads are formed by mounting MR elements of MR heads and magnetic gaps in inductive heads so that they are exposed from an outer periphery of a rotary drum. End portions of the MR elements of the MR heads are positioned at the same height H0′, and end portions defining the magnetic gaps in the inductive heads are positioned at the same height H0. The rotary head assembly is used in a helical-scanning-type magnetic recording and reproducing apparatus, which includes MR heads and inductive heads and which can provide a large reproducing operation output when forming azimuth angles at the magnetic gaps using thin-film magnetic heads.

Abstract: A rotating drum includes a magnetic head, a head base, and a holding member. The magnetic head is attached to the holding member which is attached to the head base while the magnetic head is in resilient contact with the top of a conical projection integrated with an end face of the head base, whereby the magnetic head is supported by the rotating drum via the head base.

Abstract: A rotary drum device and a helical scan magnetic recording/reproducing apparatus employing an MR head as a playback magnetic head. The rotary drum device and the helical scan magnetic recording/reproducing apparatus each include a cylindrically-shaped rotary drum, an inductive magnetic head loaded on the rotary drum so that its portion is protruded from the outer periphery of the rotary drum and a magneto-resistive effect magnetic head loaded on the rotary drum so that its portion is protruded from the outer periphery of the rotary drum. An amount of protrusion from the outer periphery of the rotary drum of the magneto-resistive effect magnetic head is smaller than an amount of protrusion from the outer periphery of the rotary drum of the inductive magnetic head.

Abstract: A core chip includes a magnetic core having a magnetic gap and a coil formed around the magnetic core. A head base includes a first main face on which a wiring pattern is formed, and a second main face on which the core chip is mounted. A conductive wire derived from the coil is electrically connected by extending only via the first main face. One end portion of the first main face is slanted and the core chip is mounted on the one end portion of the second main face. A recess or a slit is formed on the slanted portion of the first main face to extend the conductive wire therein.

Abstract: A rotary head drum device includes a rotary drum and a plurality of rotary heads mounted on the rotary drum. The rotary heads record and reproduce a signal on and from a magnetic tape. The rotary heads are as follows. First and second rotary heads for an information signal in a low-frequency range are opposed to each other diametrically with respect to the rotary drum, and are different from each other in azimuth angle. A third rotary head is designed for digital signals in frequency ranges higher than the frequency range of the information signal, and for first and second operation modes being different from each other in data transmission rate. A fourth rotary head for a digital signal in the second operation mode is opposed to the third rotary head diametrically with respect to the rotary drum, and is equal in azimuth angle to the third rotary head.

Abstract: An assembly including at least one chip with an embedded magnetic head. A base and/or a cover includes at least partially a housing in which the at least one chip is embedded. Such an assembly may find particular application to a magnetic recording system.

Abstract: In a rotary head apparatus a first reproducing magnetic head and a second reproducing magnetic head are oppositely arranged between a rotating shaft; and a first recording magnetic head and a second recording magnetic head are also oppositely arranged between the rotating shaft. One of the magnetic head elements of the first recording magnetic head and one of the magnetic head elements a of the second recording magnetic head are connected to a first channel of a rotary transformer; and the other magnetic head element of the first recording magnetic head and the other magnetic head element of the second recording magnetic head are connected to a second channel of the rotary transformer, to thereby enable simultaneous recording and reproducing.

Abstract: A helical scan drum design for use in non-tracking tape devices which assures 70% coverage of a track to be read by overscanning with at least two read heads at approximate 1× speed. The present invention further provides a simulation method for evaluating potential drum designs for such overscan applications. The preferred drum design uses pairs of like-azimuth read heads positioned on the rotating drum such that in combination they overlap the scan of a track by 130% the track width. These dimensions assure at least 70% coverage of each track by at least one of the pair of heads at up to 1× speed while assuring no overlap with another like-azimuth recorded track. The simulation method allows for evaluation of potential drum designs by accepting parameters describing the intended drum application and then simulating track read operations over a plurality of simulated tracks to determine the efficacy of the design over a range of tape speeds and gap widths.

Abstract: A helical-scan system performs recording and reproduction on a magnetic tape by using a recording and reproducing head 5 comprising m magnetic head elements 7 (where m is 2 or larger integer). During this recording and reproduction, the following relationships are satisfied among a track width W for each of the head elements 7, a track pitch Tp between the head elements 7, and a feed amount S for a magnetic tape 6.

Abstract: A helical scan drum design for use in non-tracking tape devices which assures 70% coverage of a track to be read by overscanning with at least two read heads at approximate 1× speed. The present invention further provides a simulation method for evaluating potential drum designs for such overscan applications. The preferred drum design uses pairs of like-azimuth read heads positioned on the rotating drum such that in combination they overlap the scan of a track by 130% the track width. These dimensions assure at least 70% coverage of each track by at least one of the pair of heads at up to 1× speed while assuring no overlap with another like-azimuth recorded track. The simulation method allows for evaluation of potential drum designs by accepting parameters describing the intended drum application and then simulating track read operations over a plurality of simulated tracks to determine the efficacy of the design over a range of tape speeds and gap widths.