98 results about "Entry angle" patented technology

A dimple pattern for a golf ball with multiple sets of dimples is disclosed herein. Each of the multiple sets of dimples has a different entry radius. A preferred set of dimples is eighteen different dimples. The dimples may cover as much as eighty-seven percent of the surface of the golf ball. The unique dimple pattern allows a golf ball to have shallow dimples with steeper entry angles. In a preferred embodiment, the golf ball has 382 dimples with eleven different diameters and eighteen different entry radii.

A system and method for improving a player's efficiency in shooting by providing a player with various shooting challenge routines at which a player makes either a total number of shots or a total number shots in a row. Statistics regarding the player's performance are stored, printed and / or evaluated and the player can use the information to improve his or her efficiency at one or more of the plurality of different locations where the player shoots the basketball. In another embodiment, a measuring or detection system is used in combination with or separate from a ball launcher. The system is adapted to measure at least one of a distance of a player from the a launcher, height of a shot made by the player after catching a basketball, release angle, release time, or arc of a shot; entry angle of the basketball into a goal; hold or release time; or shot arc.

A disclosed device provides a trajectory detection and feedback system. The system is capable of detecting one or more moving objects in free flight, analyzing a trajectory of each object and providing immediate feedback information to a human that has launched the object into flight, and / or one or more observers in the area. In a particular embodiment, a non-intrusive machine vision system that remotely detects trajectories of moving objects may be used to evaluate trajectory parameters for a basketball shot at a basketball hoop by a player. The feedback information, such as a trajectory entry angle into the basketball hoop and / or an entry velocity into the hoop for the shot, may be output to the player in an auditory format using a sound projection device. The system may be operable to be set-up and to operate in a substantially autonomous manner.

An ultrasound needle guide system for use with an ultrasound transducer and method of use of the guide system to provide predictable trajectories for puncture devices at various depths. The needle guide system basically consists of a bracket and a needle guide. The bracket is arranged to be releasably secured to the ultrasound transducer. The transducer / bracket assembly is then placed into an isolating sterile cover. The needle guide is arranged to be readily attached, e.g., snap-fit, to the transducer / bracket with the cover interposed therebetween. The needle guide can be provided in various versions for differing puncture device sizes and various entry angles in relation to the transducer. In one embodiment the needle guide is arranged to establish plural predetermined entry angles.

A microscope includes at least one illuminating lens configured to guide at least one illuminating beam in the form of a light sheet for illuminating at least one specimen to be examined. The microscope also includes at least one detection lens configured to capture at least one detection beam issuing from the at least one specimen to be examined. The at least one illuminating lens has an optical axis at an angle α, which is not equal to 90°, to an optical axis of the at least one detection lens. The at least one illuminating beam enters the at least one illuminating lens at an entry angle β such that the light sheet lies within a focal plane of the at least one detection lens.

A novel optical assembly apparatus for coupling optical energy and a related method for creating the novel optical assembly apparatus are disclosed. In one embodiment, the novel optical assembly apparatus includes a high-index contrast waveguide constructed on a semiconductor die or another base substrate with an aligned optical coupling section, a grating coupler etched onto a surface, a micro mirror with an acute angle relative to the surface, and a waveguide taper that narrows an optical beam width. A light ray entered into the optical coupling section is redirected by the micro mirror to form a perpendicular ray entry angle with the grating coupler. The grating coupler then efficiently couples the light ray with the waveguide taper, which in turn narrows the optical beam width. The light ray may originate from a semiconductor die or from an optical fiber, which is purposefully aligned with the high-index contrast waveguide.

A system and method are provided for using a computer system to assist in planning a trajectory (960A, 960B) for a surgical insertion into a skull. The method comprises providing the computer system with a three-dimensional representation of the skull and of critical objects located within the skull, wherein the critical objects comprise anatomical features to be avoided during the surgical insertion. The method further comprises providing the computer system with a target location (770, 970) for the insertion within the skull. The method further comprises generating by the computer system a first set comprising a plurality of entry points, each entry point (760) representing a surface location on the skull, and each entry point (760) being associated (2D) with a trajectory (960A, 960B) from the entry point (760) to the target location (770, 970). The method further comprises discarding by the computer system entry points from the first set to form a second, reduced set comprising a plurality of entry points, wherein an entry point (760) is discarded from the first set of entry points if the entry point (760) has an entry angle which fails a condition for being substantially perpendicular to the skull surface. For each entry point (760) in the second set, the computer system assess the entry point (760) against a set of one or more criteria, wherein the set of one or more criteria includes a risk factor based on the separation between the critical objects and the trajectory (960A, 960B) which is associated with said entry point (760)). This risk factor may be calculated by integrating f(x) along the trajectory (960A, 960B) associated (2D) with the entry point (760), where x represents distance along the trajectory (960A, 960B) to a sample point, and f(x) is a function based on distance from the sample point at distance x to a critical object which is nearest to said sample point.

A system and method are provided for using a computer system to assist in planning a trajectory (960A, 960B) for a surgical insertion into a skull. The method comprises providing the computer system with a three-dimensional representation of the skull and of critical objects located within the skull, wherein the critical objects comprise anatomical features to be avoided during the surgical insertion. The method further comprises providing the computer system with a target location (770, 970) for the insertion within the skull. The method further comprises generating by the computer system a first set comprising a plurality of entry points, each entry point (760) representing a surface location on the skull, and each entry point (760) being associated (2D) with a trajectory (960A, 960B) from the entry point (760) to the target location (770, 970). The method further comprises discarding by the computer system entry points from the first set to form a second, reduced set comprising a plurality of entry points, wherein an entry point (760) is discarded from the first set of entry points if the entry point (760) has an entry angle which fails a condition for being substantially perpendicular to the skull surface. For each entry point (760) in the second set, the computer system assess the entry point (760) against a set of one or more criteria, wherein the set of one or more criteria includes a risk factor based on the separation between the critical objects and the trajectory (960A, 960B) which is associated with said entry point (760)). This risk factor may be calculated by integrating f(x) along the trajectory (960A, 960B) associated (2D) with the entry point (760), where x represents distance along the trajectory (960A, 960B) to a sample point, and f(x) is a function based on distance from the sample point at distance x to a critical object which is nearest to said sample point.

Method and various devices and systems directed towards teaching, training and developing a shooter to increase the accuracy of shooting a basketball are provided. The method comprises shooting a basketball with centerline straightness, 43-45 degree basketball hoop entry angle and 11 inch shot-depth. Embodiments of the physical devices of the invention, which may be used singly or in various combination, comprise a centerline-straightness target acquisition portion, a shot-depth target acquisition potion and an arc-angle target acquisition portion that teach, develop and reinforce consistent, accurate basketball shooting. A bracket assembly is disclosed for detachably attaching the device embodiments to a basketball backboard above the basketball hoop rim.

A microscope includes at least one illuminating lens configured to guide at least one illuminating beam in the form of a light sheet for illuminating at least one specimen to be examined. The microscope also includes at least one detection lens configured to capture at least one detection beam issuing from the at least one specimen to be examined. The at least one illuminating lens has an optical axis at an angle α, which is not equal to 90°, to an optical axis of the at least one detection lens. The at least one illuminating beam enters the at least one illuminating lens at an entry angle β such that the light sheet lies within a focal plane of the at least one detection lens.