A bicycle shoe cleat positioning device for use in determining the position of a bicycle shoe cleat is provided. The bicycle shoe cleat positioning device comprises a base portion, a holding portion connected to the base portion, a coupler configured to connect to the holding portion, a cleat connector, a connecting member, and a cleat positioning assembly. The cleat positioning assembly comprises a first positioner configured to determine a first position of the cleat connector about a first axis, a second positioner configured to determine a second position of the cleat connector along a second axis, and a third positioner configured to determine a third position of the cleat connector along a third axis.

Disclosed herein are system, method, and computer program product embodiments for analyzing a person's gait through image analysis of the person's footwear. An embodiment operates by receiving an image associated with a shoe sole, the image displaying one or more cells forming part of a tread pattern of the shoe sole. The system then determining, based on the image, the wear levels of the cells and analyzes the wear levels to determine a wear pattern of the shoe sole. The system transmits information associated with the wear pattern for display in an interface of a computing device.

The invention relates to a one-piece protective toe cap for safety footwear, forming a concave frame consisting of a front wall with connected side walls, the upper edges of which are joined by a concave surface along the profile of the last. The contour or edge of the flange of the toe cap is provided with a recess in order to house a tab and provide comfort, as well as improving the appearance of the footwear (not shown in these documents). The design withstands impact tests of approximately 101.7 to 146.7 Joules (10.4 to 14.95 kgf-m), leaving clearance of approximately 11 mm to 14 mm in the capped shoe and not only at the tip of the cap.

The invention relates to a one-piece protective toe cap for safety footwear, forming a concave frame consisting of a front wall with connected side walls, the upper edges of which are joined by a concave surface along the profile of the last. The contour or edge of the flange of the toe cap is provided with a recess in order to house a tab and provide comfort, as well as improving the appearance of the footwear (not shown in these documents). The design withstands impact tests of approximately 101.7 to 146.7 Joules (10.4 to 14.95 kgf-m), leaving clearance of approximately 11 mm to 14 mm in the capped shoe and not only at the tip of the cap.

A shoe manufacturing system (100) processes a to-be-bonded surface (11a) of an upper (11) before bonding a sole to the upper (11). The shoe manufacturing system (100) includes a holding platform (10), a camera (20a, 20b), an applicator (30), a robot arm (40), and a control device (60). The control device (60) identifies a boundary of the to-be-bonded surface (11a) of the upper (11) that is to serve as a master model M among a plurality of uppers (11), for defining an area of the to-be-bonded surface (11a) to be processed, based on three-dimensional shape data of the master model M acquired by the camera (20a). The control device (60) controls the robot arm (40) for each of the uppers (11) (such as products P1 to P3) other than the master model M, to cause the applicator (30) to apply an adhesive to the area of the to-be-bonded surface (11a) enclosed by the identified boundary.

A shoe manufacturing system (100) processes a to-be-bonded surface (11a) of an upper (11) before bonding a sole to the upper (11). The shoe manufacturing system (100) includes a holding platform (10), a camera (20a, 20b), an applicator (30), a robot arm (40), and a control device (60). The control device (60) identifies a boundary of the to-be-bonded surface (11a) of the upper (11) that is to serve as a master model M among a plurality of uppers (11), for defining an area of the to-be-bonded surface (11a) to be processed, based on three-dimensional shape data of the master model M acquired by the camera (20a). The control device (60) controls the robot arm (40) for each of the uppers (11) (such as products P1 to P3) other than the master model M, to cause the applicator (30) to apply an adhesive to the area of the to-be-bonded surface (11a) enclosed by the identified boundary.

Apparatus and systems disclosed herein are designed to be used to study various forces acting on an athletic field or an athletic surface caused by the interaction between a shoe and the turf or athletic surface during a simulated impact. Various surfaces can be tested and analyzed, including assessing deceleration, acceleration and cutting traction potential on the surfaces. The disclosed apparatuses and systems allow for the testing of a wide variety of footwear, at any desired impact angle, and at various simulated forces. Methods, systems, and computer readable media for generating graphical representations associated with surface performance test information are also disclosed herein.

Apparatus and systems disclosed herein are designed to be used to study various forces acting on an athletic field or an athletic surface caused by the interaction between a shoe and the turf or athletic surface during a simulated impact. Various surfaces can be tested and analyzed, including assessing deceleration, acceleration and cutting traction potential on the surfaces. The disclosed apparatuses and systems allow for the testing of a wide variety of footwear, at any desired impact angle, and at various simulated forces. Methods, systems, and computer readable media for generating graphical representations associated with surface performance test information are also disclosed herein.

The method can determine physical properties of the ground stepped upon by a user wearing a footwear incorporating an accelerometer, and includes: receiving a raw signal from the accelerometer during at least one step being taken by the user on the ground; identifying, in the received raw signal, at least one characteristic signature; associating the at least one characteristic signature to physical properties of the ground; and generating a signal indicating the physical properties based on said association. The generated signal can further be used to advise a user of a risk of falling based on at least the physical properties of the ground.

Embodiments are directed towards recommending a shoe and insole combination for a consumer. A variety of shoe information, insole information, and consumer foot information may be determined, which may include heel width, a width or shape, a length, a height, and arch characteristics. The foot information, the shoe information for a plurality of shoes, and the insole information for a plurality of insoles may be compared to determine at least one combination of shoe and insole that is compatible with the consumer's foot. Based on this comparison of foot information, shoe information, and insole information, a recommendation of at least one shoe and insole combination may be determined and provided to a user and/or the consumer.