1. An information reproducing apparatus comprising:
a light source for generating linearly polarized light;
a medium having an information unit field and a plurality of linear marks disposed in the information unit field in overlapping relation to one another and extending in different directions from one another;
an optical head disposed between the light source and the medium, the optical head having a fine aperture;
polarized light control means for controlling the linearly polarized light generated by the light source to pass through the fine aperture of the optical head to generate near-field light having a preselected polarization direction and to irradiate the linear marks in the information unit field of the medium with the near-field light so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of each of the linear marks;
a detector for detecting light scattered by the linear mark irradiated with the near-field light; and
a signal processing circuit that processes a signal from the detector corresponding to the detected scattered light, the signal processing circuit having a control circuit having a head drive circuit for carrying out accesstracking control of the optical head and a read data output control circuit for outputting read data.
2. An information reproducing apparatus according to claim 1; wherein the signal processing circuit acquires data in accordance with an intensity of the signal from the detector corresponding to the detected scattered light.
3. An information reproducing apparatus according to claim 1; wherein the plurality of linear marks comprise a plurality of linear data marks and a plurality of tracking marks disposed in overlapping relation to the plurality of linear data marks; and wherein the signal processing circuit has a difference circuit that calculates a difference of signals for tracking and a read data signal processing circuit for processing a signal for data access, the difference circuit providing to the head drive circuit signals that control a head drive actuator that drives the optical head.
4. An information reproducing apparatus according to claim 1; wherein each of the linear marks comprises a projection having a linear edge; wherein the near-field light irradiates each projection so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each projection; and wherein the detector detects light scattered by the linear edge of each projection irradiated with near-field light.
5. An information reproducing apparatus according to claim 1; wherein each of the linear marks comprises a groove having a linear edge formed in the medium; wherein the near-field light irradiates each groove so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each groove; and wherein the detector detects light scattered by the linear edge of each groove irradiated with near-field light.
6. An information reproducing apparatus according to claim 1; wherein each of the linear marks comprises a plurality of substances having a linear interface and formed in a planar surface of the medium, the substances having a different optical property from that of the medium; wherein the near-field light irradiates each substance so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear interface of each substance; and wherein the detector detects light scattered by the linear interface of each substance irradiated with near-field light.
7. An information reproducing apparatus according to claim 6; wherein the different optical property is a different refractive index.
8. An information reproducing apparatus comprising:
a light source for generating linearly polarized light;
a medium having an information unit field and a plurality of linear marks disposed in the information unit field in overlapping relation to one another and extending in different directions from one another;
an optical head disposed between the light source and the medium, the optical head having a fine aperture;
polarized light control means for controlling the linearly polarized light generated by the light source to pass through the fine aperture of the optical head to generate near-field light and to irradiate the linear marks disposed in the information unit field of the medium with the near-field light, and for controlling a direction of polarization of the near-field light so that the direction of polarization of the near-field light irradiated on the linear marks is orthogonal to a longitudinal axis of each of the linear marks;
a detector for detecting light scattered by the linear marks irradiated with the near-field light; and
a signal processing circuit that processes a signal from the detector corresponding to the detected scattered light, the signal processing circuit having a control circuit having a head drive circuit for carrying out accesstracking control of the optical head and a read data output control circuit for outputting read data.
9. An information reproducing apparatus according to claim 8; wherein the signal processing circuit acquires multiple value data from the signal.
10. An information reproducing apparatus according to claim 8; wherein the plurality of linear marks comprise linear data marks and a plurality of tracking marks disposed in overlapping relation to the plurality of linear data marks; and wherein the signal processing circuit has a difference circuit that calculates a difference of signals for tracking and a read data signal processing circuit for processing a signal for data access, the difference circuit providing to the head drive circuit signals that control a head drive actuator that drives the optical head.
11. An information reproducing apparatus according to claim 8; wherein each of the linear marks comprises a projection having a linear edge; wherein the near-field light irradiates each projection so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each projection; and wherein the detector detects light scattered by the linear edge of each projection irradiated with near-field light.
12. An information reproducing apparatus according to claim 8; wherein each of the linear marks comprises a groove having a linear edge formed in the medium; wherein the near-field light irradiates each groove so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each groove; and wherein the detector detects light scattered by the linear edge of each groove irradiated with near-field light.
13. An information reproducing apparatus according to claim 8; wherein each of the linear marks comprises a plurality of substances having a linear interface and formed in a planar surface of the medium, the substances having a different optical property from that of the medium; wherein the near-field light irradiates each substance so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear interface of each substance; and wherein the detector detects light scattered by the linear interface of each substance irradiated with near-field light.
14. An information reproducing apparatus according to claim 13; wherein the different optical property is a different refractive index.
15. An information reproducing apparatus comprising:
a medium having a plurality of information unit fields and a plurality of linear marks disposed in each of the information unit fields in overlapping relation to one another and extending in different directions from one another;
an optical head disposed over the medium and having a fine aperture;
light generating means for generating linearly polarized light and directing the linearly polarized light through the fine aperture of the optical head to generate near-field light and to irradiate at least one of the linear marks in the information unit fields of the medium with the near-field light;
control means for controlling a direction of polarization of the near-field light so that the direction of polarization of the near-field light irradiated on the at least one linear mark is orthogonal to a longitudinal axis of the at least one linear mark;
detecting means for detecting light scattered by the linear mark irradiated with the near-field light; and
signal processing means for processing a signal from the detecting means corresponding to the detected scattered light, the signal processing means comprising a control circuit having a head drive circuit for carrying out accesstracking control of the optical head and a read data output control circuit for outputting read data.
16. An information reproducing apparatus according to claim 15; wherein the plurality of linear marks comprise a plurality of linear data marks and a plurality of tracking marks disposed in overlapping relation to the plurality of linear data marks; and wherein the signal processing means further comprises a difference circuit that calculates a difference of signals for tracking and a read data signal processing circuit for processing a signal for data access, the difference circuit providing to the head drive circuit signals that control a head drive actuator that drives the optical head.
17. An information reproducing apparatus according to claim 15; wherein each of the linear marks comprises a projection having a linear edge; wherein the near-field light irradiates each projection so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each projection; and wherein the detecting means detects light scattered by the linear edge of each projection irradiated with near-field light.
18. An information reproducing apparatus according to claim 15; wherein each of the linear marks comprises a groove having a linear edge formed in the medium; wherein the near-field light irradiates each groove so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each groove; and wherein the detecting means detects light scattered by the linear edge of each groove irradiated with near-field light.
19. An information reproducing apparatus according to claim 15; wherein each of the linear marks comprises a plurality of substances having a linear interface and formed in a planar surface of the medium, the substances having a different optical property from that of the medium; wherein the near-field light irradiates each substance so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear interface of each substance; and wherein the detecting means detects light scattered by the linear interface of each substance irradiated with near-field light.
20. An information reproducing apparatus according to claim 19; wherein the different optical property is a different refractive index.
21. An information reproducing method, comprising the steps of:
providing a medium having a plurality of information unit fields and a plurality of linear marks disposed in each of the unit fields in overlapping relation to one another and extending in different directions from one another;
generating near-field light by directing linearly polarized light through a fine aperture of an optical head;
irradiating at least one of the linear marks in the respective information unit field of the medium with the near-field light while controlling a direction of polarization of the near-field light so that the direction of polarization of the near-field light irradiated on the at least one linear mark is orthogonal to a longitudinal axis of the at least one linear mark;
detecting light scattered by the linear mark irradiated with the near-field light; and
processing a signal corresponding to the detected scattered light including carrying out accesstracking control of the optical head and outputting read data.
22. An information reproducing method according to claim 21; wherein the plurality of linear marks comprise a plurality of linear data marks and a plurality of tracking marks disposed in overlapping relation to the plurality of linear data marks; and further comprising the steps of calculating a difference of signals for tracking and processing a signal for data access, and providing to the head drive circuit the processed signal to control a head drive actuator that drives the optical head.
23. An information reproducing method according to claim 21; wherein each of the linear marks comprises a projection having a linear edge; wherein the irradiating step comprises irradiating each of the projections with near-field light so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each projection; and wherein the detecting step comprises detecting light scattered by the linear edge of each projection irradiated with near-field light.
24. An information reproducing method according to claim 21; wherein each of the linear marks comprises a groove having a linear edge formed in the medium; wherein the irradiating step comprises irradiating each of the grooves with near-field light so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear edge of each groove; and wherein the detecting step comprises detecting light scattered by the linear edge of each groove irradiated with near-field light.
25. An information reproducing method according to claim 21; wherein each of the linear marks comprises a plurality of substances having a linear interface and formed in a planar surface of the medium, the substances having a different optical property from that of the medium; wherein the irradiating step comprises irradiating each of the substances with near-field light so that the preselected polarization direction of the near-field light is orthogonal to a longitudinal axis of the linear interface of each substance; and wherein the detecting step comprises detecting light scattered by the linear interface of each substance irradiated with near-field light.
26. An information reproducing method according to claim 25; wherein the different optical property is a different refractive index.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. A collapsible target, the target comprising:
a frame, the frame being collapsible from an open, unfolded configuration to a closed, folded configuration;
a fabric housing mounted on the frame, the housing comprising a plurality of panels joined together to form an inner compartment, one of the panels having a window formed therein to provide an opening to the compartment;
a target assembly mounted in the compartment behind the window, the target assembly comprising a base and a self-resetting spinner rotatably mounted to the base.
2. The collapsible target of claim 1 wherein the spinner is rotatably mounted to the base on an axle, the axle being illuminable.
3. The collapsible target of claim 2, wherein the spinner comprises a plurality of apertures to permit light from the axle to illuminate the target assembly.
4. The collapsible target of claim 2, the spinner further comprising a plurality of loops and grooves on a rear side thereof, the plurality of loops and grooves for engaging the axle, thereby allowing the spinner to rotate about the axle.
5. The collapsible target of claim 2, the base further comprising a pair of receptacles positioned diametrically opposite of each other, the receptacles for receiving and holding opposite ends of the axle.
6. The collapsible target of claim 5, each receptacle comprising a base and a lid frictionally engaged with one another to hold the axle.
7. The collapsible target of claim 1 wherein the target assembly is mounted in the compartment with a plurality of flexible rubber tubes.
8. The collapsible target of claim 7, the base further comprising a plurality of posts, wherein the flexible rubber tubes are secured to the posts.
9. The collapsible target of claim 7, the base further comprising a plurality of grooves formed along an outer circumference, the grooves configured to engage portions of the flexible rubber tubes.
10. The collapsible target of claim 1, the frame further comprising a plurality of tubular members movable relative to one another to allow the frame to move between the open, unfolded configuration and the closed, folded configuration.
11. The collapsible target of claim 1, wherein the fabric housing is padded along its edges.
12. The collapsible target of claim 1, the panels comprising a front panel, side panels, a rear panel and a bottom panel.
13. The collapsible of target of claim 12, the fabric housing further comprising an apron at a front side of the frame extending below the front panel.
14. The collapsible target of claim 12, wherein the window is formed in the front panel.
15. The collapsible target of claim 12, wherein the compartment has a generally right-triangular cross-section with the front panel and bottom panel forming legs of the right triangle and the rear panel forming a hypotenuse of the right triangle.
16. The collapsible target of claim 12, the panels further comprising a catch panel mounted in the compartment.
17. The collapsible target of claim 1, wherein the spinner is angled along its diameter.
18. The collapsible target of claim 1, the spinner further comprising upper projections and lower projections to serve as weights to return the spinner to a reset position after being struck and rotated by a projectile.
19. The collapsible target of claim 18, wherein in the number of upper projections is less than the number of lower projections such that the spinner is bottom heavy.