The invention relates to devices and methods for designing and manufacturing customized footwear, and components thereof. An exemplary method includes a method of designing at least a portion of a sole of an article of footwear customized for a user. The method includes the steps of determining at least one input parameter related to a user, analyzing the at least one input parameter to determine at least one performance metric of a foot of the user, and determining at least one customized structural characteristic of at least a portion of a sole of an article of footwear for the user based on the performance metric.

The invention relates to devices and methods for designing and manufacturing customized footwear, and components thereof. An exemplary method includes a method of designing at least a portion of a sole of an article of footwear customized for a user. The method includes the steps of determining at least one input parameter related to a user, analyzing the at least one input parameter to determine at least one performance metric of a foot of the user, and determining at least one customized structural characteristic of at least a portion of a sole of an article of footwear for the user based on the performance metric.

An outsole for an athletic shoe that includes a heel section and a forefoot section. The heel and forefoot sections are on the outer surface of the outsole. The forefoot section includes a tread pattern that provides first and second ground friction forces. The first ground friction force promotes rotation in a first rotational direction about a rotation point of the forefoot section. The second ground friction force restricts rotation in a second rotational direction about the rotation point. The second rotational direction is opposite of the first rotational direction and the second ground friction force is greater than the first ground friction force.

An outsole for an athletic shoe that includes a heel section and a forefoot section. The heel and forefoot sections are on the outer surface of the outsole. The forefoot section includes a tread pattern that provides first and second ground friction forces. The first ground friction force promotes rotation in a first rotational direction about a rotation point of the forefoot section. The second ground friction force restricts rotation in a second rotational direction about the rotation point. The second rotational direction is opposite of the first rotational direction and the second ground friction force is greater than the first ground friction force.

A cleat and base assembly for permitting blind alignment and engagement to one another. The cleat is disposed on an underside of a shoe sole and includes a forward cleat engagement edge and a rearward cleat engagement edge displaced at a distance along a longitudinal axis of the shoe sole. The base assembly can be provided on a bicycle pedal and includes a forward base engagement edge and a rearward base engagement edge configured to releasably retain or couple the forward and rearward cleat engagement edges, respectively. A pair of guides are disposed at angles relative to the longitudinal axis of the shoe sole, the pair of guides converging at opposing sides of one of the forward or rearward clear engagement edges to permit blind alignment and engagement of the cleat to the base assembly.

A cleat and base assembly for permitting blind alignment and engagement to one another. The cleat is disposed on an underside of a shoe sole and includes a forward cleat engagement edge and a rearward cleat engagement edge displaced at a distance along a longitudinal axis of the shoe sole. The base assembly can be provided on a bicycle pedal and includes a forward base engagement edge and a rearward base engagement edge configured to releasably retain or couple the forward and rearward cleat engagement edges, respectively. A pair of guides are disposed at angles relative to the longitudinal axis of the shoe sole, the pair of guides converging at opposing sides of one of the forward or rearward clear engagement edges to permit blind alignment and engagement of the cleat to the base assembly.

An outsole for an athletic shoe that includes a heel section and a forefoot section. The heel and forefoot sections are on the outer surface of the outsole. The forefoot section includes a tread pattern that provides first and second ground friction forces. The first ground friction force promotes rotation in a first rotational direction about a rotation point of the forefoot section. The second ground friction force restricts rotation in a second rotational direction about the rotation point. The second rotational direction is opposite of the first rotational direction and the second ground friction force is greater than the first ground friction force.

A sole for an article of footwear, which has a medial side, a lateral side, a forefoot region, a midfoot region, and a heel region, includes a set of ridges concentrically aligned around and emanating outwardly from an epicenter. The epicenter is disposed within the forefoot region and is closer to the medial side than the lateral side. The set of ridges is disposed in each of the forefoot region, the midfoot region, and the heel region. A set of spaces extends concentrically between respective ridges of the set of ridges. The set of ridges includes a plurality of short portions having a height that is smaller than heights of adjacent tall portions of the set of ridges. A flex zone is defined by at least some of the plurality of short portions and is configured to flex more than one or more stiffening zones of the sole.

Sole structures for articles of footwear (e.g., outsole components) have one or more of: a base plate having a V-shaped support structure with lateral and medial support members extending forward from a base support area located in a heel or rear midfoot area of the outsole component; a base plate having a matrix structure with recesses or openings formed between rib elements that make up the matrix structure; and/or a base plate having a rear heel support. The base plates may be made, at least in part, as unitary, one-piece constructions, using selective laser sintering or other three-dimensional printing and/or rapid manufacturing additive fabrication techniques.

Sole structures for articles of footwear (e.g., outsole components) have one or more of: a base plate having a V-shaped support structure with lateral and medial support members extending forward from a base support area located in a heel or rear midfoot area of the outsole component; a base plate having a matrix structure with recesses or openings formed between rib elements that make up the matrix structure; and/or a base plate having a rear heel support. The base plates may be made, at least in part, as unitary, one-piece constructions, using selective laser sintering or other three-dimensional printing and/or rapid manufacturing additive fabrication techniques.