In at least some embodiments, an orthotic footbed assembly includes a three-dimensional footbed that closely approximates a size and configuration of a particular foot and at least one orthotic feature additively coupled to the three-dimensional footbed. In at least some other embodiments, a method of making the orthotic footbed assembly includes direct printing of orthotic features onto a 3-D footbed. Another method includes indirect printing of orthotic features and applying these features onto to a 3-D footbed. And yet another method includes direct printing of orthotic features onto a 2-D blank footbed and then conducting a three-dimensional forming operation to make the orthotic footbed assembly.

Disclosed aspects pertain to surface analysis based on wearable sensor data. Sensor data can be acquired from pressure-sensitive wearable sensors, such as shoe insole sensors, based on interaction with a surface. A location can also be determined for the sensor data with respect to a surface utilizing a positioning system. The sensor data can be utilized to determine surface properties at a particular location. Further, a graphical representation of the surface properties and location can be generated and conveyed for display on a display. Furthermore, movement instructions can be provided to aid in analysis of an entire surface, and recommendations can be made regarding surface maintenance based on collected sensor data.

An insole including a base; an electronic element provided to the base; a connection line configured to extend from the electronic element and to pass through the base; and a cover provided on a top surface of the base to cover the electronic element and configured to be separable from the base.

The invention relates to a method (500) for calculating personalized parameter values of a new custom sole for the design of custom soles, said method comprising: a step of loading (530) posture or mobility parameter values (101) of a user; a step of loading (540) shoe parameter values (201); a step of calculating (550) one or more personalized parameter values of a new custom sole (301).

A sensor layer for determining temperature profiles on a skin surface. The sensor layer includes at least one ply, a contact layer with the skin surface, the contact layer being arranged on a top side of the at least one ply, a plurality of temperature sensors arranged at least one of in the at least one ply and on the top side of the at least one ply, and conductor tracks arranged at least one of in the at least one ply and on the top side of the at least one ply. The conductor tracks are electrically connected to the plurality of temperature sensors so that the sensor layer is formed to be flexible and so that a temperature difference on the skin surface can be determined via the contact layer.

The present disclosure is related to three-dimensionally printed articles for use in footwear and associated systems and methods. In some embodiments, a three-dimensionally printed article may comprise a closed-cell foam. The closed-cell foam may have a gradient in and/or may be a single integrated material. In some embodiments, a three-dimensionally printed article may comprise a sensor. The use of such arrangements can, according to certain embodiments, allow for the production of improved articles of footwear and/or customized articles of footwear.

Provided is a smart insole including a support layer; a plurality of pressure sensors provided to the support layer and configured to sense a pressure; a plurality of vibrators provided to the support layer and configured to generate a vibration; and a controller configured to determine a center of pressure (COP) based on a pressure sensed by each of the plurality of pressure sensors and to control the plurality of vibrators based on a positional relationship between a setting point and the COP.

Provided herein are embodiments of a shoe component. The shoe component may include a toebox, an insole, an adhesive membrane, a thermal-resistant insert, a midsole, and an outsole. The insert may further include a footbed. The footbed may include an upper surface and a bottom surface. The insert may further include an upper laminate on the upper surface of the footbed and a lower laminate on the bottom surface of the footbed.

The present invention relates to a pad for strengthening the muscle of the sole of the foot, and an insole including same. The subject matter of the present invention is a pad for strengthening the muscle of the sole of the foot, and an insole including same, the pad comprising: an arch support part for supporting the arch portion; a forefoot support part formed at the front of the arch support part to support the forefoot portion; and a connecting passage part for connecting the arch support part and the forefoot support part, wherein weight moves to the forefoot portion through the outer side of the sole of the foot after a load is applied to the rearfoot portion during walking, and the metatarsal bones come into contact with the forefoot support part and are stimulated so that driving power is generated in the direction between the big toe and the second toe, and thus walking is corrected.

A footwear system includes a sensorized insole and a charger. The sensorized insole has an insole bulk having a foot-facing upper surface. A sensor is embedded in the insole bulk for measuring a parameter of a user's foot, a battery is embedded in the insole bulk for providing energy to the sensor, and a receiver pod is embedded in the insole bulk and is spaced from the foot-facing upper surface for wirelessly receiving energy and providing energy to the battery. The charger provides energy to the receiver pod, and includes a cable for connecting to an energy source, and a transmitter pod electrically connected to the cable for receiving energy from the cable and wirelessly transmitting energy to the receiver pod. The transmitter pod is positionable against the foot-facing upper surface to wirelessly provide energy to the receiver pod through the insole bulk.