The presently-disclosed subject matter relates to an inner sole for a shoe, and methods of using the inner sole to detect, monitor, and transmit information regarding use of the inner sole.
Tracker devices such as the Nike+™ are known which are inserted in a shoe and which provide a limited amount of information on the distance and pace of a run or walk.
At present, if a user wishes to obtain information on their gait, foot strike and/or player loading as a guidance for buying a new pair of shoes or for adjusting their movements and/or stride, they typically have to go to a sportswear store and run on a treadmill whereupon a camera will produce an image which can be used to analyze their gait.
The present invention aims to improve shoe tracking systems.
The presently-disclosed subject matter meets some or all of the above-identified needs, as will become evident to those of ordinary skill in the art after a study of information provided in this document.
This Summary describes several embodiments of the presently-disclosed subject matter, and in many cases lists variations and permutations of these embodiments. This Summary is merely exemplary of the numerous and varied embodiments. Mention of one or more representative features of a given embodiment is likewise exemplary. To avoid excessive repetition, this Summary does not list or suggest all possible combinations of such features.
According to a first aspect of the present invention, there is provided an inner sole for a shoe, the inner sole comprising a main body made at least in part of a compressible material and a number of components embedded within the main body, the components comprising: a pressure sensor; a transmitter; a global positioning tracking device; an accelerometer; a power source connected to one or more of the pressure sensor, transmitter, global positioning tracking device and accelerometer; and a control circuit configured to receive data from the pressure sensor, global positioning tracking device and accelerometer transmit it via the transmitter to a remote location.
The present invention can include a pressure sensor, a global positioning tracking device, and an accelerometer, all of which gather data concerning the manner in which a user is running or walking. This information is then collected and transmitted to a remote location to enable information to be obtained which is hitherto unavailable in the prior art.
In some embodiments, the inner sole may further comprise a subscriber identity module (SIM) card. The SIM card may be removable, or preferably may be an integrated e-SIM. The transmitter may connect the inner sole to a local device with a SIM or e-SIM which has cellular communication capabilities.
The pressure sensor may comprise first and second pressure sensing areas, wherein the first pressure sensing area is positioned in a heel region of the main body of the inner sole, and the second pressure sensing area is positioned in a forefront region of the main body of the inner sole.
Alternatively, the inner sole may further comprise a second pressure sensor, wherein the first pressure sensor is positioned in the heel region of the main body and the second pressure sensor is positioned in a forefront region of the main body.
The inner sole may be provided as a removable inner sole for a shoe. However, it can also be directly integrated into a finished shoe.
The inner sole may preferably also comprise an altimeter connected to the control circuit.
The inner sole may preferably also comprise an electrocardiographic sensor connected to the control circuit.
The power source may be any suitable source such as a high capacity capacitor. However, it is preferably a battery. This may be replaceable, removable for recharging or rechargeable in situ. When the battery is rechargeable in situ, the inner sole preferably comprises a power inlet port.
The present invention also extends to a second aspect which is a system comprising an inner sole according to a first aspect of the present invention together with a remote device to receive information from the transmitter of the inner sole, the remote device having means to process and manipulate the received data to display the manipulated information. The remote device can be provided with an appropriate operating system and compatible software, most commonly in the form of an app, to decode and display the received data. The received data may be displayed on the remote device itself, on other third party devices, and/or on a social media platform. The app is preferably customizable to allow the user to select which information is displayed and the manner in which it is displayed. The inner sole may also be provided with means to process and manipulate information before it is sent from the transmitter of the inner sole. In some instances, the processing and manipulating of information can include determining from the information received from the pressure sensor how a user's weight is distributed as their foot lands on the ground and/or how much pressure is put on the user's feet when moving from side to side. When the means to process and manipulate information is provided in the inner sole, this allows the amount of information and the frequency of communication to a remote location to be reduced.
The remote device may be the user's personal device. Alternatively, or in addition, data may be sent to a remote device which is operated by a second user. As an example, this data may include the location of the inner soles so that the second user to track the progress of the first user. This location data may be overlaid with a map of the first user's route, such as in a race condition.
The system may further comprise a database of data relating to a number of brands and/or types of footwear (including brands and/or types of inner soles), the data concerning the ability of the footwear to support the sole of the user; and means for comparing information from the pressure sensor with the database and providing an indication to the user of a preferred brand and/or type of footwear based on this comparison. This indication may allow the user to place an order for the particular brand and/or type of footwear. Using known techniques such as affiliate marketing, the user can then be directed to a point of purchase, such as an online retailer.
The data concerning the ability of the footwear to support the sole of the user may be stored in a further database, along with an identifier of the worn brand and/or type of footwear for use by manufacturers to determine how to make improvements to newer versions of the brand and/or type of footwear.
This forms a third aspect of the present invention which is a method of determining optimum footwear use for a user, the method comprising using a system according to the second aspect of the present invention and comprising the steps of: determining from the information received from the pressure sensor how a user's weight is distributed as their foot lands on the ground and/or how much pressure they are putting on their feet when moving from side to side; transmitting this information to the remote device, the remote device having access to data for a number of brands and/or types of footwear, the data concerning the ability of a brand and/or type of footwear to support the sole of a user; and comparing the distribution of the sensed forces against the data of the stored brands and/or types of footwear, and recommending a preferred brand and/or type of footwear based on this comparison. Using known techniques such as affiliate marketing, the user can then be directed to a point of purchase, such as an online retailer.
At present, if a user wishes to obtain information on their gait, foot strike and/or player loading as a guidance for buying a new pair of shoes, they typically have to go to a sportswear store and run on a treadmill whereupon a camera will produce an image which can be used analyses their gait.
With the present invention, information on the nature of their gait, foot strike and/or player loading can be obtained in real time during normal use. The indication of preferred footwear may, for example, be a recommendation to obtain a particular shoe or a range of shoes. In addition, the information regarding the nature of the user's gait, foot strike and/or player loading may be used in conjunction with known biomechanics, sports science knowledge and expertise to recommend an ideal running style. In addition or alternatively, event specific recommendations such as running speed, power output and cadence may be provided for a particular event in which the user is taking part. The recommendation may also include condition related advice, such as when to take a rest or hydrate.
According to a fourth aspect of the present invention, there is provided a method of determining the length of time a person is off the ground, the method comprising providing the person with at least one inner sole according to a first aspect of the present invention, using a combination of accelerometer to determine a sharp acceleration and the pressure sensor to determine a simultaneous sharp drop in the sensed pressure indicating a take-off time signifying that the person has left contact with the ground; using a combination of the accelerometer to determine a sharp deceleration and the pressure sensor to determine a simultaneous sharp increase in the sensed pressure indicating a landing time signifying the person has landed; and measuring the time between the take-off and landing conditions to determine the time for which a user had left the ground. Data from the altimeter may be used in connection with, or as an alternative to, the above methods for determining the take-off and landing conditions.
This allows the inner sole to measure the “hang time”, namely the time for which a wearer of the shoe is off the ground. This can provide important statistical information for sports coaches, and can also provide interesting information for spectators.
The invention will now be described in detail, by way of example only, with reference to the accompanying drawings in which:
An embodiment of the present invention is shown as the inner sole 100 of
The inner sole 100 is formed by a hardware layer 40 and a multi-layer sensor layer 2. As shown in
The sensor layer 2 will now be described in more detail with respect to
This material provides the contact point for the user's foot 1. On the underside of the layer 10, away from the user's foot 1, first and second sensing arrangements 11, 15 are provided. The first sensing arrangement 11 is located towards the front of the layer 10 and comprises a sensing area 12 positioned to sense the force applied by the user's forefoot. In electrical connection with the sensing area 12 is a tracking section 13 which is in turn in electrical connection with a contact pad 14. The second sensing arrangement 15 is located toward the back of the layer 10 and comprises a sensing area 16 positioned to sense the force applied by the user's heel. In electrical connection with the sensing area 16 is a tracking section 17 which is in turn in electrical connection with a contact pad 18.
The middle layer 20 of the multi-layer sensor layer 2 is shown in
The bottom layer 30 of the multi-layer sensor layer 2 is shown in
The three layers 10, 20, 30 of the multi-layer sensor layer 2 may be formed together in a multi-stage forming process. Alternatively, the layers 10, 20, 30 may be adhesively bonded to one another.
The hardware layer 40 is depicted in
A composite schematic showing the multi-layer sensor 2 joined together and attached to the hardware layer 40 is shown in
This application claims the benefit of U.S. Provisional Application No. 62/546,655, filed Aug. 17, 2017, which is hereby incorporated by reference.
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Number | Date | Country | |
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20190053566 A1 | Feb 2019 | US |
Number | Date | Country | |
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62546655 | Aug 2017 | US |