A method of making an orthotic is disclosed. The method includes the steps of taking measurements relating to a foot and then creating a digital representation of an orthotic on a display device based on said measurements. This digital representation of the orthotic having a heel portion for supporting a heel of a person and a distal portion located in front of the heel portion which can be divided into first and second distal portions. The thickness of the digital representation of the first and second distal portions is then varied such that one of the distal portions is thicker than the other. Finally, an additive manufacturing technique, using a substantially uniform material or materials, is used to create a physical version of the digital representation of the orthotic.

A method for producing a shoe, in particular a sports shoe. In order to provide an optimally fitting shoe in a simple manner, the method comprises the following steps according to the invention: a) Measuring at least one individual characteristic of the foot of a person and/or one walking characteristic of the person by means of a measuring device; b) Determining the progression of a material characteristic and/or mechanical characteristic of at least one sole or one sole part of the shoe along at least one direction of extend of the sole or of the sole part in accordance with the values measured according to step a) using a specified algorithm or a specified rule; c) Producing the sole or a sole part of the shoe, wherein the material characteristics and/or mechanical characteristics are varied along the at least one direction of extend of the sole or of the sole part such that the material characteristic and/or mechanical characteristics at least approximately correspond to the progression determined according to step b); d) Connecting the sole produced according to step c) or the sole part to an upper in order to complete the shoe.

Example shoe manufacturing methods and related computer readable medium for implementing a portion of said manufacturing methods are disclosed herein. In some examples, the method includes placing an upper member about an upper portion of a last, wherein the last is a form for the shoe. In addition, the method includes producing a lasting based on data relating to a foot of a user, and attaching the lasting to the upper member, wherein the lasting extends over a lower portion of the last. Further, the method includes molding a sole onto the lasting and the upper member; and removing the last from the upper member.

A system for managing foot length information of a growing person is to be provided. A foot length information management system includes: a measurement unit that measures foot length; a storage unit that stores multiple patterns of growth curve information; an age information input unit into which age information of a customer is entered; and a growth curve information selecting unit that refers to the age information to select growth curve information corresponding to foot length measured by the measurement unit, from among the multiple patterns of growth curve information. The foot length information management system may further include a recording unit in which past foot length is recorded, and the growth curve information selecting unit may select growth curve information based on foot length recorded in the recording unit and foot length measured by the measurement unit.

Methods, systems, and non-transitory computer readable media for providing a user portal to facilitate modeling of foot-related data are described.

An article of footwear includes an upper and a sole structure with a sole member. The sole member can include a set of apertures that is formed along various surfaces of the sole member. The sole member can be manufactured using a customized cushioning sole system, forming generally circular patterns throughout the sole member. A user's foot morphology and/or preferences may be used to design the sole member.

A midsole for an article of footwear including a three-dimensional mesh including interconnected unit cells and methods of making the same. The interconnected unit cells each include a plurality of struts defining a three-dimensional shape. The interconnected unit cells are connected at nodes having a valence number defined by the number of struts connected at that node. The valence number of the nodes may vary to provide customized characteristics to zones or portions of the midsole. The plurality of interconnected unit cells may be organized in a warped cubic lattice structure. The warped cubic lattice structure and the size/shape of interconnected unit cells may vary to provide customized characteristics to zones or portions of the midsole. The three-dimensional mesh may be customized based on a biometric data profile for an individual, or group of individuals. The midsole may be manufactured using an additive manufacturing process.

A structure in which complexity of the moving path of the nozzle during forming is suppressed even if the structure has regions with different elasticity and a manufacturing method for a structure that can suppress complexity of the moving path of the nozzle when forming the structure with regions with different elasticity. The structure includes a formed body with a linear structure formed of a linear resin. The formed body includes first and second elastic regions, and the linear resin forming the first elastic region is thinner than the linear resin forming the second elastic region.

Disclosed is a method for manufacturing an insole for a shoe. The method comprises providing instructions to a person to attain a first pose; capturing a first three-dimensional image of a first foot of the person in the first pose; providing instructions to the person to attain a second pose, wherein the second pose is different from the first pose; capturing a second three-dimensional image of a second foot of the person in the second pose; generating a first three-dimensional model of the first foot from the first three-dimensional image; generating a second three-dimensional model of the second foot from the second three-dimensional model; manufacturing a first insole for the first foot based on the first three-dimensional model of the first foot; and manufacturing a second insole for the second foot based on the second three-dimensional model of the second foot.

In a markerless foot size estimation device 100, a shape data input unit 10 acquires three-dimensional shape data of a foot of a subject and stores the three-dimensional shape data in a shape data storage unit 20. A characteristic extraction unit 30 extracts foot shape characteristics from the three-dimensional shape data of a subject's foot stored in the shape data storage unit 20, and stores the foot shape characteristics in a shape characteristic storage unit 40. A machine learning unit 50 uses, as teacher data, foot shape characteristics and arch height stored in the shape characteristic storage unit 40 to create, through machine learning, an estimation model used to estimate arch height based on foot shape characteristics, and stores the estimation model in an estimation model storage unit 60. An estimation output unit 70 uses the estimation model stored in the estimation model storage unit 60 to estimate arch height based on extracted shape characteristics and outputs the arch height.