US20140221160A1

Movatterモバイル変換

Info

Publication number: US20140221160A1
Application number: US14/343,379
Authority: US
Inventors: Marc Scott Hardy; Andrei Richard Frank
Original assignee: Paofit Holdings Pte Ltd
Current assignee: Paofit Holdings Pte Ltd
Priority date: 2011-09-08
Filing date: 2012-09-10
Publication date: 2014-08-07
Also published as: WO2013034987A2; WO2013034987A3; EP2753242A2; EP2753242A4

Abstract

Embodiments of the present disclosure provide a sensor devices and corresponding systems for various fitness equipments to determine information corresponding to one or more activities of a user utilizing the equipments. The information may include speed, pressure, stride, and one or more other activities of the user. In an embodiment, the information may be measured when the sensor device is in constant contact with a fitness equipment (treadmill) but is not fastened to the exercise treadmill equipment. The information may be measured by one or more sensors that may be embedded in the sensor device. The measured information may be transmitted from the sensor device to data processor of an external device. Such information corresponding to various activities of the user may be utilized further for various applications.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application relates to U.S. Provisional Patent Application, “System and method for merging objects with a real-life video stream,” filed on Sep. 8, 2011, Ser. No. 61/532,464, which is hereby incorporated by reference in its entirety.

TECHNICAL FIELD

The present invention generally relates to sensors technology, and in particular, to a sensor device and system for detecting user information through fitness equipment.

BACKGROUND ART

There is a growing interest in developing entertainment or other types of application for fitness equipment. Some equipment manufacturers have added viewing screens, plug-in capabilities for music players such as the iPod or iPhone, and even Internet connecting capabilities to some fitness equipment machines. In some cases the information about the user's performance is logged in such a way as to be accessible at a later point in time or shared with others on the web. Further, there is interest in using the fitness equipment as part of a wider entertainment or gaming experience, where the activity itself (for example jogging, cycling, etc.) or parameters thereof (for example speed, direction, force) are used as controls of computer games, video players or other entertaining add-ons to the exercise activity.

Further, information regarding user's exercise pattern may need to be recorded for determining health status of the user. For example, the exercise parameters such as speed, direction, pressure may need to be checked regularly so as to keep the health of the user under control. Existing systems provide options for ways to open up or bolt on permanent hardware add-ons to these machines for measuring some parameters such as speed of the user, direction of the user and calories burnt by the user. However opening up a particular equipment to add any functionality is a complicated, expensive and time consuming task, and will in most cases permanently alter or damage the equipment. For example, if ten equipments are placed in a gym then each equipment needs to be configured separately to provide the functionality for measuring some parameters related to user's performance on the equipment. This adds on to the expense of any fitness centre in configuring or reconfiguring the equipment for measuring performance of the user.

Based on the aforementioned and to provide further related functionalities and convenience, there is a need for means by which usage information related to a user (such as speed, direction, force, incline, etc.) can be extracted real time from a fitness equipment machine without altering or damaging the equipment itself and with minimal fitting requirement. Thus, the means should be arranged in minimal time and cost to provide an ease in determining various information related to the user.

DISCLOSURE OF THE EMBODIMENTS

Embodiments for the present invention provide a sensor system for collecting user activity data from an exercise apparatus. The sensor system may include a wheel mechanism configured to be in physical contact with a moving tread of the exercise apparatus for measuring a plurality of characteristics corresponding to the moving tread. Further, the sensor system may include a plurality of sensors configured for determining a plurality of parameters corresponding to one or more activities performed by a user of the exercise apparatus. The plurality of parameters may be determined based on the measured plurality of characteristics of the moving tread. Further, the sensor may include a data communication interface for transmitting the measured plurality of parameters to a data processor. Herein, the physical contact between the wheel mechanism and the moving tread is maintained by a spring-based mechanism.

Hereinabove, the exercise apparatus may have a tread (such as a treadmill) that needs to be in contact with the sensor device. The abovementioned sensor system may be implemented by a sensor device for determining information corresponding to activities of the user on the exercise apparatus.

Further, embodiments of the present invention provide a sensor device for collecting user activity data from an exercise apparatus. The sensor device includes a housing comprising multiple layers containing a plurality of sensors, a circuit board and a power source. The housing may be attached to a pedal of the exercise apparatus. The plurality of sensors measures one or more parameters corresponding to one or more activities performed by a user on the pedal of the exercise apparatus. Further, the sensor device may include a data communication interface coupled to the circuit board, the data communication interface configured for transmitting the measured parameters to a data processor.

Herein above, the multiple layers may include an upper layer against which the user's foot is placed and a lower layer that is placed against a pedal surface of the exercise apparatus. Further, sensors and data communication interface, and a board-based electrical circuit for managing the power sources, sensor data and data communication interface may be provided. Also, a system may be provided to attach the housing (plate-type structure) to the pedal of the exercise apparatus. Additionally, in an embodiment, the sensor device may implement a system to determine information corresponding to activities of the user.

BRIEF DESCRIPTION OF THE DRAWINGS

Having thus described the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein

FIG. 1 is an exemplary block diagram representing implementation of a sensor system, in accordance with various embodiments of the present disclosure;

FIG. 2 depicts an exemplary implementation of a sensor device in accordance with some embodiments of the present disclosure;

FIG. 3 depicts a more detailed diagram of the sensor device in accordance with some embodiments of the present disclosure;

FIG. 4 illustrates a more detailed diagram of an alternative structure of the sensor device in accordance with some embodiments of the present disclosure;

FIG. 5 illustrates a process of measuring tilt or angle of a treadmill using the sensor device in accordance with some embodiments of the present disclosure;

FIG. 6 illustrates components of a base of the sensor device in accordance with some embodiments of the present disclosure;

FIG. 7 illustrates a detailed view of a Primary Wheel of the sensor device in accordance with some embodiments of the present disclosure;

FIG. 8 illustrates a schematic diagram of the Main Circuit Board in accordance with some embodiments of the present disclosure;

FIG. 9 illustrates a schematic diagram of the Sub Circuit Board in accordance with some embodiments of the present disclosure;

FIGS. 10A,10B and10C illustrate a primary wheel, a main circuit board and a sub circuit board in accordance with some embodiments of the present disclosure;

FIGS. 11A and 11B depict pictorial view of the sensor device in accordance with some embodiments of the present disclosure;

FIG. 12 illustrates implementation of the sensor device by utilizing an infrared sensor, in accordance with an embodiment of the present disclosure;

FIG. 13 illustrates a sensor device depicting the underside of a pedal plate in accordance with some embodiments of the present disclosure;

FIG. 14 illustrates a sensor device depicting the top side of the pedal plate in accordance with some embodiments of the present disclosure;

FIG. 15 illustrates a side view of peizo-based sensors that connects to the pedal plate in accordance with some embodiments of the present invention;

FIG. 16 is a diagram depicting underside view of the piezo-based sensor that may be utilized for the pedal plate in accordance with some embodiments of the present invention;

FIG. 17 illustrates an implementation of the sensor device utilizing a pedal plate in accordance with some embodiments of the present disclosure; and

FIG. 18 illustrates a flow chart depicting power management in accordance with an embodiment of the present disclosure.

MODES FOR CARRYING OUT THE INVENTION AND INDUSTRIAL APPLICABILITY

Illustrative embodiments of the invention now will be described more fully henceforth with reference to the accompanying drawings, in which some, but not all embodiments of the invention are shown. Indeed, the invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.

The present disclosure provides a device implementing a sensor system that may be utilized with an exercise apparatus for determining and transferring information corresponding to one or more activities performed by a user on the exercise apparatus. The exercise apparatus may include, but is not limited to, an apparatus that involves usage of a tread, such as a treadmill and any apparatus involving usage of pedals, such as elliptical machines, rowers, cycles, bicycles and the like. In an embodiment, the device implementing the sensor system may be placed under the exercise apparatus in a way that the device comes in contact with the tread of the exercise apparatus but does not require configuring the exercise apparatus in anyway. The device may measure data related to the user's activities on the tread of the exercise apparatus through variations in the moving tread.

In another embodiment, the device may include independent plate sensors for various exercise apparatuses such as, but are not limited to, elliptical machines, rowers and cycles. An independent pedal plate sensor may include a flexible plate that may be placed on a pedal area of any fitness machine having a pedal. The user may apply pressure to the pedal or may move thereon. Such pressure and movement may be measured by the device having plate sensors.

The measured data may be stored and/or transmitted to an external data processor. The measured data may help in determining user's information such as, but is not limited to, movement (e.g., cadence) and force (pressure). In an embodiment, the data may be utilized further to know the health status of the user utilizing the exercise apparatus for fitness.

Referring now toFIG. 1 that illustrates an exemplary block diagram100 representing implementation of asensor system102, in accordance with various embodiments of the present disclosure. Thesensor system102 may be a device or implemented by a device for determining and transmitting data related to a user's activities, on anexercise apparatus104, to anyexternal data processor106 of any external device such as a PC, a laptop, a smart-phone and a like. As represented through a connection link, the device or thesensor system102 may be in physical contact with theexercise apparatus104. For example, theexercise apparatus104 may be a treadmill and the device implementing thesensor system102 may be placed on the floor directly underneath the treadmill where a section of the tread on the underside is exposed.

Thesensor system102 may include awheel mechanism108 that may be linked with a plurality ofsensors110 for determining information corresponding to the user of theexercise apparatus104 based on the functioning ofwheel mechanism108. The determined information (hereinafter may interchangeably be referred to as ‘sensor data’) may be transmitted to theexternal processor106 through acommunication interface112.

Thewheel mechanism108 may be in physical contact with a moving tread of the exercise apparatus for measuring a plurality of characteristics related to the moving tread. The characteristics related to the moving tread may include, but are not limited to, variations in speed of the moving tread, and tilt of the moving tread. Thewheel mechanism108 may include a primary wheel and a secondary wheel that may be utilized for measuring speed and tilt of the moving tread. In an embodiment, the secondary wheel may be smaller in size and lighter than the primary wheel. The wheels (primary wheel and the secondary wheel) may be placed in contact with the tread from underside of the tread of theexercise apparatus104 as thewheels mechanism108 may allow the wheels to swing upwards to the underside of the tread.

Further, the wheels mechanism may include support means such as swing arms with each wheel. For example, the primary wheel may be connected to a primary swing arm from one side; and the secondary wheel may be connected to one side of a secondary swing arm. Further, the secondary wheel may be connected to the primary wheel through the other side thereof. Hereinafter, the primary wheel and the secondary wheel may collectively be referred to as ‘wheels’. The concept of the primary wheel and the secondary wheel is explained in detail further in conjunction withFIGS. 3,4,5 and7 of this disclosure.

Further, the primary wheel may include a sub circuit board (explained further in conjunction withFIG. 7) that may include thesensors110 to determine a plurality of parameters corresponding to one or more activities performed by a user of the exercise apparatus. The plurality of parameters may be determined by thesensors110 based on the measured plurality of characteristics of the moving tread. For example, rotation speed of the primary wheel may increase or decrease based on the moving tread of theexercise apparatus104. Similarly, the height of the wheels may vary based on variation in the angle of the moving tread. Thus, accordingly, based on the characteristics of the moving tread (such as speed and height of the moving tread, downward force applied (on the wheels) by the moving tread and the like), as determined by the wheels mechanism, thesensors110 may detect one or more activities performed by the user on the moving tread. For example, thesensors110 may determine the speed of the user; and pressure/force applied by the user by analyzing rotation speed of the primary wheel, variation in heights between the primary and secondary wheels, downwards pressure applied to the moving tread by the user on the tread.

Further, a range of sensors may be used to measure the parameters related to activities of the user as explained in detail in conjunction withFIGS. 2 and 7. The measured plurality of parameters may be transmitted to theexternal processor106 via thecommunication interface112.

Thecommunication interface112 may utilize wireless data transmission technology to transmit the determined sensor data to a remote data processor. Such wireless data transmission technology may include, but is not limited to, radio frequency, blue tooth, Wi-Fi, NFC (Near Field Communications) and infrared. Further, thecommunication interface112 may utilize a wired connection by using USB HID protocol or the like to transmit the determined sensor data to thedata processor106.

In an embodiment, thecommunication interface112 may include a transceiver that may be placed onto the floor near theexercise apparatus104 for receiving the sensor data and transmitting the received sensor data to the external device (such as a PC or a laptop and the like). For example, a transceiver may be placed on the floor close to pedal plates (of the exercise apparatus) for receiving the sensor data wirelessly from the pedal plates and then transmitting it wirelessly or via wired transmission, to the external device that may include a software for using the received data (sensor data). Further, in an embodiment, the sensor data may be processed by a processor (not shown) of thesensor system102. For example, thesensor system102 may utilize an inbuilt processor to convert Analog signals of the sensor data into digital signals before transmitting the data to theexternal processor106. Similarly, a USB HID transceiver may be plugged into the external device, having theprocessor106, to receive the sensor data and transmit the received sensor data to another external device.

Further, thesensor system102 may include apower source114 and a main circuit board, such as acircuit board116. Thepower source114 may be utilized for powering thesensors110 and thecommunication interface112. Thepower source114 and thecommunication interface112 may be managed by acircuit board116. In an embodiment,power source114 may be implemented through a power management circuit that may be managed through thecircuit board116. Thecircuit board116 is explained further in conjunction withFIG. 6.

FIG. 2 depicts an exemplary implementation of a sensor device in accordance with some embodiments of the present disclosure. As shown, asensor device202 may be placed below an exercise apparatus, such as atreadmill204 to make a physical contact with atread206 of thetreadmill204. Such physical contact between thesensor device202 and the tread of thetreadmill204 may be required for measuring data corresponding to activities of a user on thetreadmill204. For example, if a user changes an angle of thetreadmill204, increases a speed of thetreadmill204 or performs any other activity on thetreadmill204 then thesensor device202 may sense the user's activities accordingly.

Further, thesensor device202 may transmit the data corresponding to the user's activities through radiofrequency signal transmission208 to a USB HIDradio frequency transceiver210 that may be placed into anexternal device212. Theexternal device212 may include, but is not limited to, a PC, a laptop, and a mobile device. Theexternal device212 may be placed in the vicinity of thetreadmill204 to receive the data from thesensor device202 and to transmit the data further to any other device.

Thesensor device202 may include a base214 that may be placed on the floor under thetreadmill204. The base214 may include a main circuit board, a power management circuit, and a communication interface. Further, thebase214 may be linked to a wheel mechanism (including, but is not limited to, a primary wheel and a secondary wheel) through a primary swing arm. Hereinafter, the primary wheel and the secondary wheel may collectively be referred to as ‘wheels’. Theprimary swing arm216 may be attached to the base at one end and to a primary wheel at another end so that a force that may be applied to theprimary swing arm216 may cause the other arm to swing in upward direction until the wheels (the primary wheel and the secondary wheel) make contact with the underside of the tread of thetreadmill204.

Further, theprimary swing arm216 may be attached to a secondary swing arm axis at the other end. The secondary swing arm axis corresponds to a secondary swing arm that may be attached to the primary wheel at one end and a secondary wheel at another end. The secondary swing arm may also be linked to a sub circuit board that may be located next to the primary wheel. Thus, the secondary swing arm may be linked to theprimary swing arm216 at the secondary swing axis that may be positioned in a manner such that the primary wheel and the secondary wheel may remain in suspended broadly horizontal balance (like traditional scales).

The wheels may measure the characteristics related to tread's movements and accordingly thesensor device202 may determine various parameters corresponding to one or more activities of the user of thetreadmill204. The concept of the wheels (the primary wheel and the secondary wheel) is explained further in conjunction withFIGS. 3,4,7 and10A.

In an embodiment, thesensor device202 may include apressure pad218 between floor and thetread206. Thepressure pad218 may be connected to an extendable detachableelectrical cord220 that may be attached to thebase214 and ultimately connected to the main circuit board of thesensor device202. Thepressure pad218 may include a pressure sensor to determine if actually anyone is present and moving on the treadmill when the treadmill is in motion. A secondary benefit of the pressure pad218 (may be referred to as ‘pressure sensor218’) may include an ability to derive the runners pace and therefore stride (when combined with speed data).

Further, thepressure sensor218 may be connected to an extendable cord that may be attached to thebase214 and thereby ultimately linked to the main circuit board (not shown) located in thebase214. The pressure pad (or the pressure sensor)218 may be placed directly under one of the load bearing points of contact between the treadmill and the ground on which it is placed as illustrated byFIG. 2. Thepressure pad218 may measure a change in pressure and relay this data back to the main circuit board of thebase214. In an embodiment, the pressure sensor may include a tailor-made piezo sensor pressure pad that may include reverse amplification of the sensor output signal. Thepressure sensor218 may be designed to require a degree of pressure to be applied to determine the force applied by a user of the treadmill. For example, a light touch may not be utilized in determining a load and thereby enhance accuracy in determining exact load through the user's weight/activities when the user uses the treadmill (or any other similar exercise apparatus).

Further, information corresponding to the force or pressure applied by the user may be determined by utilizing the pressure sensor. The information may be analyzed to measure various parameters corresponding to activities of the user. The measured parameters may be transmitted through the base214 to theexternal device212 that may have a software to receive and further utilize the received data for various applications. The measured parameters may determine if there is a frequent change in pressure exerted by the user that may be attributed to activities of the user on the treadmill. Thesensor device202 may transmit its sensor readings (data) either directly (i.e. wired) with a remote computer through aUSB interface210 that may be using USB HID protocol and transmitting 50 data packets per second. Further, the sensor data may be transmitted wirelessly using a monolithic RF GFSK transceiver which may receive and transmit data intelligently. In an embodiment, the working ISM frequency band of the monolithic RF GFSK transceiver may vary between 2.4 and 2.5 GHz.

It may be appreciated by a person skilled in the art that the device may have a built-in frequency synthesizer, power amplifier, crystal oscillator, modulator and other functional modules. By usingRadio Frequency transmission208, thesensor device202 may transmit data for up to 20 meters and may require no line of sight. Further, in an embodiment, thesensor device202 itself may include a software application (that may be embedded in the base214 (of the sensor device202)) to analyze the sensor's data corresponding to activities (such as pressure exerted) performed by the user on the treadmill (or any other similar exercise apparatus).

Further, in an embodiment, the information determined by thesensor device202 may be processed by an inbuilt processor and/or an external processor. For example, thesensor device202 may include a processor for converting an analog signal into a digital signal prior to transmitting the determined information to theexternal device212. In another embodiment, thesensor device202 may transmit the determined information to theexternal device212 that may have a software application to utilize the information corresponding to the user's activities.

Referring toFIG. 3 that depicts a more detailed diagram of thesensor device202 in accordance with some embodiments of the present disclosure. As shown, thesensor device202 may communicate with anexternal device212, such as a laptop, through aUSB interface210 utilized by the external device. Thesensor device202 may be placed under an exercise apparatus, such as treadmill, as explained previously in conjunction withFIG. 2.

Thesensor device202 may include a base302 that may be placed on thefloor304. The base302 may be in contact with a wheel mechanism containing aprimary wheel306 and asecondary wheel308. Thesecondary wheel308 may be smaller and lighter than theprimary wheel306. Hereinafter, theprimary wheel306 and thesecondary wheel308 may collectively be referred to as ‘wheels’. The base302 may be connected to theprimary wheel306 through a main swing arm310 (may interchangeably be referred to as a ‘primary arm’). Themain swing arm310 may further be attached to an axis of asecondary swing arm314. Further, aprimary spring system316 may be fixed to an axis of themain swing arm310 so that a force that may be applied to themain swing arm310 may cause another end of theprimary swing arm310 to move upward until the wheels make contact with underside of the treadmill's tread, such as thetread206.

Further, thesecondary swing arm312 may be connected to theprimary wheel306 at one end and thesecondary wheel308 at another end. Further, thesecondary swing arm312 may be attached to asub circuit board318 that may be located alongside theprimary wheel306. Additionally, thesecondary swing arm312 may be linked to theprimary swing arm310 at theaxis314 of the secondary swing arm. Theaxis314 may be positioned such that the two wheels at either end remain in suspended broadly horizontal balance.

In an embodiment, theprimary wheel306 may contain plurality of magnets that may be placed in sequence of alternative directions, such as north, south, north . . . and so on. Further, theprimary wheel306 may contain internal bearings that may enable the wheel to spin around a fixed axis. An image of the primary wheel is provided inFIG. 10A.

Further, thebase302 may include amain circuit board320 that may be a 32-bit embedded chip based on the ARM Cortex-M3 Kernel. Themain circuit board320 may manage a USB interface, a power management circuit, a radio frequency (wireless) interface, pressure measurement circuit and RS232 communication interface. In an embodiment, the RS232 communication interface may receive data packets every 13 ms from thesub circuit board318. Further, the RS232 may be a source of power for thesub circuit board318. The base302 may further include a rechargeable lithium battery322 (located near to the main circuit board320) and aUSB input port324 that may link to theMain Circuit Board320. TheUSB port324 may provide (optional) a data transfer link and a power source to recharge the battery. Further, apressure pad218 on an extendable detachableelectrical cord220 may be attached to thebase302 and ultimately be connected to themain circuit board320. A schematic of themain circuit board320 is provided inFIG. 8 and an image of the main circuit board is provided inFIG. 10B.

Further, thesub circuit board318 may be an 8-bit microcontroller among STM8S series of ST Microelectronics. The Sub Circuit Board may include an RS232 interface that may connect via a wire link to themain circuit board320, a speed sensor circuit (not shown) and tilt angle circuit (not shown). A schematic of the Sub Circuit Board is provided inFIG. 9 and an image of the Sub Circuit Board is provided inFIG. 10C.

Further, a radiofrequency signal transmission208 may be from themain circuit board320 that may be received by a USB HIDradio frequency transceiver210 that is placed into the external device212 (such as a laptop, a desktop, a smart-phone and the like) positioned in the vicinity of the exercise apparatus, such as a treadmill.

Thesensor device202 may be implemented to measure activities performed by a user of the exercise apparatus by maintaining contact with an exposed underside of the tread. As shown thesensor device202 may be placed on thefloor304 making contact with thetread206 of the treadmill. Themain swing arm310 may lift theprimary wheel306 and thesecondary Wheel308 until both the swing arms make contact with the underside of thetread206. It may be noted that thesensor device202 may be placed in a position to enable the wheels clear unimpeded access to the tread so that the wheels do not come into contact with the treadmill's frame. The sustained upward force of theprimary swing arm310 may ensure that both the primary wheel30 and thesecondary wheel308 retain contact with the tread even if the tread bounces, changes angle or changes height. The height of the base302 may be extended or themain swing arm310 may be extended to further expand the height of thesensor device202.

FIG. 4 illustrates a more detailed diagram of an alternative structure of the sensor device in accordance with some embodiments of the present disclosure.FIG. 4 includes asensor device202 that may include a wheel mechanism (containing aprimary wheel306 and asecondary wheel308, as explained previously in conjunction withFIG. 3) to measure characteristics (such as the variation in the movement and tilt) of a tread, a plurality of sensors for sensing and collecting the information corresponding to a user of an exercise apparatus (such as a treadmill) based on the measured characteristic. The collected information may be processed and provided to an external device (such as the external device212) through a communication interface (such as a USB port324).

Further, the collected information may be processed by transforming analog signal information into digital signal information prior to transmitting the information to theexternal device212. In an embodiment, the collected information may directly be sent to theexternal device212 having suitable software to utilize the collected information for any required application. Due to this, no prior processing of the collected information may be required before sending the information to theexternal device212. For example, if the information corresponding to user's activities is required for entertainment purposes or measuring health status for the user, the collected information may be processed and provided to a software application that may be required for analyzing the collected information for the required application, such as for providing entertainment, determining the health status of the user and so on.

Theexternal device212 may include a USB HID radio frequency transceiver for receiving the collected information from the sensor device and the received information may further be transmitted to any other device for the required usage. Additionally, the USB HID radio frequency transceiver may be utilized to transmit initial data values to thesensor device202 for further processing of the collected information. Thus, it may be appreciated by a person skilled in the art that thesensor device202 may further be advanced according to the required usage of the user's activities data (as collected by the sensor device202).

A key objective of the structure outlined inFIG. 2 is to keep both the primary wheel and the secondary wheel in contact with a tread regardless of the height, tilt or bounce of the treadmill. The present disclosure may provide a number of different embodiments for maintaining the contacts of the wheels with the tread.FIG. 4 may outline one such embodiment that may be understood more clearly in conjunction with descriptions ofFIGS. 2 and 3.

Specifically,FIG. 4 shows that theprimary wheel306 is placed at the end of themain swing arm310 instead of the end of the secondary swing arm312 (as shown inFIG. 2). The secondaryswing arm axis314 is changed so that it may also double up as the primary wheel axis. Further, the secondaryswing arm axis314 may also have an extension bit that may be linked to aposition cable402. Theprimary wheel306 may rotate around the secondaryswing arm axis314 with the axis itself only rotating with the movement of thesecondary swing arm312. Further, at the secondaryswing arm axis314, asecondary spring system404 may be attached that may apply an upward force to thesecondary swing arm312 so that thesecondary wheel308 may also be forced up.

Theposition cable402 may be connected at one end to an axis of themain swing arm310 located at thebase302 and at the other end thesecondary swing arm312. Theposition cable402 may be of a fixed length and set such that the highest point of thesecondary wheel308 is higher than the highest point of theprimary wheel306. The difference in height of theprimary wheel306 and thesecondary wheel308 may approximate between 20 and 30 degrees (i.e. a bit more than the maximum tilt of treadmills). Further, thesecondary wheel308 may maintain the higher position via the upward force applied from thesecondary spring system404. In an embodiment, if the treadmill tread is at a tilt of 25 degrees, then the wheels will remain in the same position relative to each other. If the treadmill tread is at a lesser angel or horizontal, then the small wheel (secondary wheel308) may be correspondingly forced down. Further, in case, the small wheel is forced down, there is some slack built up in theposition cable402, however, the slack may be minor. Further, the process of measuring tilt or angle of a treadmill using thesensor device202 is explained further in conjunction withFIG. 5.

FIG. 5 illustrates a process of measuring tilt or angle of a treadmill using the sensor device in accordance with some embodiments of the present disclosure. As shown, atread206 of an exercise apparatus (treadmill) has changed from an original horizontal position (represented by a dark grey line) to a new tilted position (shown by a dotted line). In such tilted position of the tread, aprimary wheel306 and asecondary wheel308 may be pressed up against the tread surface206 (dotted line) and thus may change their vertical heights relative to one another.

Further, as shown thesecondary wheel308 may be lifted higher than theprimary wheel306. The change in heights of thesecondary wheel308 is illustrated by anarrow502. Further, thesecondary swing arm312 may also change its angle as thesecondary swing arm312 is linked to the axis of both wheels. This change in thesecondary swing arm312 is depicted as change in its position from a dotted line of thesecondary swing arm312 to a grey solid line of thesecondary swings arm312. Further, the change in the angle of thesecondary swing arm312 may be measured by an angle sensor located on asub circuit board318 that is attached to thesecondary swing arm312. This change in the angle of thesecondary swing arm312 may provide data that may be needed to calculate the tilt of the treadmill.

In this embodiment, the angle sensor that may include a G-Cell capacitive tri-axel accelerometer (MEMS) to measure accelerated forces along the X, Y and Z axis. The sensor may be calibrated for a non-linear angle measurement and the analog data output. The analog data output may then be converted into a digital data, via a separate analogue-to-digital converter, before being transmitted to themain circuit board320 via an RS232 interface. The data may be stored to the main circuit board's flash memory where the data may be read and converted into a degree reading prior to an external transmission via the RF transceiver.

Alternative arrangements for measuring tilt in the secondary swing arm312 (based on the change in the angle of the tread206) may include placement of the tilt sensor directly on thesecondary swing arm312 or on thesecondary wheel308 instead of thesub circuit board318 located next to theprimary wheel306. Another embodiment may be the inclusion of several radar based sensors onto thebase302 and linking such sensors into themain circuit board320.

Further, the information measured by the sensor device may be communicated to an external device through acommunication interface324 of thebase302. The description corresponding to thebase302 and transmission of the sensor information to the external device is explained previously in conjunction withFIGS. 2,3, and4, thus not repeated here for the sake of brevity.

FIG. 6 illustrates components of a base of the sensor device in accordance with some embodiments of the present disclosure. Specifically,FIG. 6 depicts various components that may be involved in power management depending on available power source. The base302 may include, but is not limited to, amain circuit board320, abattery322 and a USB port (interface)324. The external power source may be provided through theUSB interface324 connected to themain circuit board320 in theBase302.

In an embodiment, a 5V power cable is connected to theUSB interface324. A Low Drop Out (LDO) voltage regulator may then be applied to reduce the working voltage used by the Circuit Board to 3.3V. An internal power source may include thebattery322 such as arechargeable lithium battery322. The battery's regular power supply may be in the range of 3.6V to 4.2V. The LDO voltage regulator used for the external power source is similarly used to reduce the battery's power supply to 3.3V. It may be appreciated by a person skilled in the art that the system embodied in this example can power itself for between 20 and 40 hours.

Further, in an embodiment, if there is no external (USB) power source, the core chip of the sensor system (implemented by the sensor device) may rely on thelithium battery322. If the lithium battery is in use, the core chip may lower the operating frequency of the sensor system to help extend the life of the battery before recharge is needed.

An LED light is also added to themain circuit board320 to detect if the battery output is below 3.6V. If it is determined that the battery output is below 3.6V, then thebattery322 may need to be recharged. Further, if there is an external (USB) power source and the core chip also detects thelithium battery322, the core chip may use the external (USB) power source to both power the circuit boards (such as the main circuit board320) and recharge the lithium battery.

Further, it may be appreciated by a person skilled in the art that the system described above may also include an energy harvesting system to further prolong the energy sources or indeed potentially render the sensor device wholly self sufficient. Using magnets in a rotating wheel to measure speed also allows the magnetic energy to be harvested for energy purposes. Further, brushless rotor motor may also be attached to a small wheel to ensure decent rotations speed. Alternatively, new technologies that can harvest energy from motion like “reverse electro-wetting” or variants thereof may be applied. However, in all instances, the level of energy harvested may need to be balanced against the total force applied to the treadmill surface which may interfere with the treadmills performance. The process of power management system of the sensor device is explained further in detail in conjunction withFIG. 18.

Referring now toFIG. 7 illustrates a detailed view of a Primary Wheel of the sensor device, such as thesensor device202, in accordance with some embodiments of the present disclosure. Specifically,FIG. 7 depicts magnets formation of theprimary wheel306 that may be utilized by a wheel mechanism of the sensor device. The description of theFIG. 4 is to focus on the primary wheel system of the wheel mechanism of the sensor device.

It may be appreciated by a person skilled in the art that the wheel mechanism may be implemented by the sensor system of the sensor device to determine the variations in various characteristics of the tread. Further, the usage of wheel mechanism may provide many advantageous features to implement the sensor system. Some of the benefits may include cheap (less cost), simple and reliable. More specifically, the wheel mechanism utilized by the sensor device may be resilient against vibration levels, various features of the tread's surface, speed, and environmental conditions. Additionally, the sensor device and wheel mechanism thereof requires just a sustained contact with the tread surface that enables movement in the wheels (of the wheel mechanism) with the movement in the tread of the treadmill and thus requires no special fitting of any kind. Further, various other aspects of the wheel mechanism (of the sensor device) may be understood when read in conjunction with description ofFIGS. 2,3,4 and5.

As depicted, the detailed view of the primary wheel that may interface with a system of a speed sensor is provided. One of the objectives of the sensor device is to independently measure the speed of the movement of a tread of an exercise apparatus (such as treadmill) without requiring any interference with the treadmill. A number of sensors may apply, although in many cases sensors may require some form of interference such as special treadmill fittings, markings applied to the tread, etc.

As shown inFIG. 4, theprimary wheel306 may have asub circuit board318 that may be located next to theprimary wheel306 of the sensor device. Thesub circuit board318 may have a sensor system that may measure the rotation of theprimary wheel306. TheSub Circuit Board318 may not rotate with thePrimary Wheel306 but rather is fixed to the movement of aSecondary Swing Arm312. One end of theSecondary Swing Arm312 may be attached to thePrimary Wheel306 and another end of thesecondary swing arm312 may be connected to a Secondary Wheel (shown inFIG. 3) of the wheel mechanism. Thesecondary swing arm312 is explained previously in conjunction withFIGS. 3,4 and5. Further, a range of sensor solutions may be utilized to independently measure the rotation of thePrimary Wheel306.

In one embodiment, a speed sensor may be utilized to measure speed of the rotation of theprimary wheel306. The speed sensor may include, but is not restricted to, one or more Hall switches that may be fixed into theSub Circuit Board318. The positions of the Hall switches may be tailored to a specific configuration of thePrimary Wheel306 and, in particular, the placement ofmagnets702 that may be built inside thePrimary Wheel306.

In an embodiment, the magnets may be built into thePrimary Wheel306 in a sequence of alternative directions such as first north, then south, and then north and so on. A chip timer counter may be set to generate a signal based on the movement of magnets with the movement of theprimary wheel306. For example, a signal may be generated in case pulse is rising that is the case when a magnet approaches a hall switch. Similarly, a signal may be generated when pulse falls that is case the magnet departs a hall switch. Due to this, two signals may be generated for every instance a magnet passes by a hall switch (although only every other magnet is valid). It may be appreciated by a person skilled in the art that more than one hall switches may be utilized for determining more data per revolution and thus increasing the accuracy of the data for a given rotation.

In another embodiment, instead of buildingmagnets702 into thePrimary Wheel306, slots or reflectors may be used in their place. For example, an LED or similar light emission may be positioned next to the slots or reflectors that may be built into thePrimary Wheel306. Accordingly, an LED or similar light sensor may position to count the light emissions that may appear through the slots or bounce off the reflectors as thePrimary Wheel306 rotates.

Additionally, in another embodiment, instead of building magnets, slots or reflectors into thePrimary Wheel306, a rotation sensor may be attached directly to an axis of thePrimary Wheel306. Herein, the axis of theprimary wheel306 may be fixed such that the rotation sensor may rotate with thePrimary Wheel306.

FIG. 8 illustrates a schematic diagram of a Main Circuit Board, such as themain circuit board320, in accordance with some embodiments of the present disclosure. The main circuit board may be utilized to enable functioning of a sensor device, such as thesensor device202, for determining activities of a user on an exercise apparatus, such as a treadmill. The main circuit board may be a 32-bit embedded chip based on the ARM Cortex-M3 kernel. Further, the main circuit board may include various components that may be connected with conductive cables.

The main circuit board may include, but is not limited to, a USB interface, a power management circuit, a wireless interface, such as radio frequency interface, a pressure management circuit and RS232 communication interface. The power to the main circuit board may be provided through a rechargeable battery, such as a lithium battery. Further, battery may be recharged through a USB input port that may be externally connected to the main circuit board. Further, the USB port may provide a data transfer link. Further, the data may be transferred through the radio frequency interface of the main circuit board. A radio frequency may be transmitted from the main circuit board that may be received by a USB HID radio frequency transceiver that may be connected to an external device placed in the vicinity of the treadmill.

Further, the main circuit board may be connected with other circuits of the sensor device. The main circuit board may receive data from a plurality of sensors and may store the received data in a flash memory of the main circuit board. The stored data may be read and processed or converted into a degree reading corresponding to the activities of the user on the tread. The processed data may be transmitted to an external device through a radio frequency transceiver.

The RS232 interface of the main circuit board may receive data packets every 13 ms from a sub circuit board. Further, the RS232 interface of the main circuit board may be a source of power for the sub circuit board. The sub circuit board is explained further in conjunction withFIG. 9.

Referring now toFIG. 9 that illustrates a schematic diagram of the Sub Circuit Board, such as thesub circuit board318, in accordance with some embodiments of the present disclosure. The sub circuit board may be positioned alongside a primary wheel, such as theprimary wheel306, of the wheel mechanism of the sensor device. The sub circuit board may include an RS232 interface that may connect to the main circuit board of the sensor device, a speed sensor circuit, and a tilt angle circuit via wired link.

The sub circuit board may include a range of sensor solutions that may be used to independently measure the rotation of the primary wheel. The sub circuit board may not rotate with the rotation of the primary wheel but may be fixed to the movement of a secondary swing arm, such as the secondary swing arm312 (as explained previously in conjunction withFIGS. 3 and 7.

In an embodiment, a speed sensor may include one or more Hall switches that may be fixed into the sub circuit board. The positions of the Hall switches may be tailored according to the specific configuration of the primary wheel. Particularly, the hall switches may be positioned based on the placement of magnets in the primary wheel. Further, a chip timer counter may be set to generate a signal for both pulse rising (when the magnet approaches a hall switch) and pulse falling state (the case when the magnet departs a hall switch). The sub circuit board may receive a power for operation from the main circuit board. Further, the functioning of the sub circuit board is explained previously in conjunction withFIGS. 3,4,5 and7. The image of the sub circuit board is depicted inFIG. 10C.

FIGS. 10A,10B and10C illustrate a primary wheel, a main circuit board and a sub circuit board, respectively, in accordance with some embodiments of the present disclosure. A sensor device, such as thesensor device202, may implement a sensor system based on a wheel mechanism, a plurality of sensors, and circuitry to provide support for implementing the operations of the sensor system. The sensor system may be implemented to determine a user's activities on an exercise apparatus without requiring any fitting mechanism for the sensor device into the exercise apparatus.

FIG. 10A depicts a primary wheel, such as the primary wheel304 (as described previously in conjunction withFIG. 3) that is a part of the wheel mechanism of the sensor device (or sensor system). Theprimary wheel304 may be in touch with a tread of an exercise apparatus (such as treadmill) and may be utilized to estimate speed of the user on the treadmill. Theprimary wheel304 may include, but is not limited to, a plurality of magnets, such as the plurality of magnets702 (as depicted inFIG. 7) that may be arranged in sequence of alternate directions. For example, a North Pole of a magnet may be next to a South Pole of another magnet and then North Pole of a third magnet and so on.

The primary wheel may be alongside a sub circuit board that may include one or more Hall switches. The positions of the Hall switches may be tailored according to the specific configuration of the primary wheel. Particularly, the hall switches may be positioned based on the placement of magnets in the primary wheel. Theprimary wheel306 is explained previously in conjunction withFIGS. 3,4,5 and7 thus detailed description for the primary wheel is not repeated here for the sake of brevity.

Further,FIG. 10B depicts an image of amain circuit board1002 that may be utilized by a sensor device. The main circuit board1003 may be same as the main circuit board320 (as explained previously in conjunction withFIGS. 3 and 6). Thus, the description corresponding to main circuit board is not repeated here for the sake of brevity. Further, acable1004 may be utilized for connecting themain circuit board1002 with various other components such as the wheel mechanism and sub circuit board of the sensor device. Further,FIG. 10C depicts an image of asub circuit board1006 that is explained previously as thesub circuit board318 in conjunction withFIGS. 3,7 and9.

FIGS. 11A and 11B depictpictorial views1100 of the sensor device, such as thesensor device202, in accordance with some embodiments of the present disclosure. As shown, thesensor device1100 may include, but is not limited to, abase1102, aprimary wheel1104, asecondary wheel1106, aprimary swing arm1108, and asecondary swing arm1110. Thebase1102, such as thebase302, may include a main circuit board, a battery and a USB port, as explained previously in conjunction withFIG. 6. Further, theprimary swing arm1108 is shown as connected to thebase1102 through one end thereof and to thesecondary swing arm1110 through another end of theprimary swing arm1108. Further, as shown, theprimary wheel1104 and thesecondary wheel1106 may be connected through thesecondary swing arm1110.

Thesensor device1100 may be placed on the floor underside of a tread of an exercise apparatus (such as a treadmill). ThePrimary Swing Arm1108 may lift thePrimary wheel1104 and theSecondary Wheels1106 upwards until both the wheels make contact with the underside of the tread. It may be noted that the sensor device may be placed in a position that enables the wheels clear unimpeded access to the tread such that the wheels do not come into contact with the treadmill frame. The sustained upward force of thePrimary Swing arm1108 may ensure both Wheels (theprimary wheel1104 and the secondary wheel1106) retain in contact with the tread even if the tread is bouncing, changes angle or changes height. Further, height extensions may be added to thebase1102 to raise the height of the wheels so as to make contact with the tread. Further, to raise the height of the wheels, thePrimary Swing Arm1108 may be extended to further expand the height range of the sensor device.

For example, as shown,FIG. 11A shows the wheels in lower position with the bent state of theprimary swing arm1108. Alternatively,FIG. 11B shows the raisedprimary swing arm1108 so as to raise the wheels up to the level of the tread (not shown).

The ‘base1102’, the ‘primary wheel1104’, the ‘secondary wheel1106’, the ‘primary swing arm1108’ and the ‘secondary swing arm1110’ are explained previously as the ‘base302’, the ‘primary wheel306’, the ‘secondary wheel308’, the ‘primary swing arm310’ and the ‘secondary swing arm312’ respectively in conjunction withFIGS. 2 to 5. Thus the detailed functional implementation of thesensor device1100 is not repeated here for the sake of brevity.

FIG. 12 illustrates implementation of a sensor device utilizing an infrared sensor, in accordance with an embodiment of the present disclosure.FIG. 12 depicts a rearview of atreadmill1202, asensor base1204, aninfrared sensor1206, anadjustable stand1208 for theinfrared sensor1206, and awired link1210 to link theinfrared sensor1206 with thesensor base1204 for base power and wireless transmission of data that may be collected by theinfrared sensor1206.

As depicted, theinfrared sensor1206 may be placed next to the treadmill to get a clear view of the surface of tread of thetreadmill1202. An infrared sensor1206 (laser sensor) that may or may not be combined with a monochrome CMOS sensor for added sensitivity, may be mounted on asmall stand1208 that may provide theinfrared sensor1206 with a clear view of the area of contact between the user and the tread.

Theinfrared sensor1206 may be linked to a Main Circuit Board, such as themain circuit board320, located in thesensor base1204 via awired connection1210. The data from theinfrared sensor1206 may be used to track movements of the user on the treadmill without requiring any contact with the user. This data (from the infrared sensor1206) may be used in place of a Primary Wheel, such as theprimary wheel306, to estimate the speed of the user on the treadmill. Further, the data from theinfrared sensor1206 may be utilized in place of using a pressure sensor, such as the pressure sensor218 (as depicted inFIG. 3), to indentify the presence of the user and force/pace corresponding to the user.

In another embodiment, a video camera (not shown) may be used in place of theinfrared sensor1206. The video camera may capture information corresponding to activities of the user using the treadmill. The video camera may be used with video analytics that may be applied to the information captured by the video camera for calculating the user's movements (if any) on the treadmill.

In yet another embodiment, a sensor may be placed on the user themselves to collect data corresponding to the user's activities that may be transmitted to the Main Circuit Board of thesensor base1204. Such sensor may be an accelerometer included in a device or object that may be held or worn by the user. For example, the sensor may be implemented through a smart phone that may collect data and can then transmit that data to the main circuit board of thesensor base1204. Further, for example, a separate accelerometer may be attached to the user's shoes that may determine the user's information such as the pace, speed and pressure applied by the user on the treadmill. The data may be transmitted from the sensor to the main circuit board via Bluetooth or an alternative wireless technology.

FIG. 13 illustrates a sensor device depicting the underside of apedal plate1300 in accordance with some embodiments of the present disclosure. The pedal plate may be attached to a pedal area of an exercise apparatus, such as elliptical machines, rowers, cycles and similar other apparatuses having pedal functionalities. A user of the exercise apparatus may apply a pressure to the pedal plate that may be placed over the pedal area to use the exercise apparatus. Thesensor device1300 may be utilized to measure various parameters, such as movement (e.g., cadence) and force (pressure) associated with one or more activities of the user on the exercise apparatus. The various parameters may be measured without requiring access to the mechanics of the exercise apparatus.

The pedal plate may be housing for number of layers containing, but is not limited to, a plurality of sensors, a circuit board and a power source. The circuit board and the power source may be designed and housed in between the user's feet and the pedal of the exercise apparatus so as to remain isolated from a pressure applied by the user on the sensor device. The multiple layers of the pedal plate (may hereinafter interchangeably be referred to as ‘plate’ or ‘housing’) may include, but are not limited to, one or more upper layers (upper plates and a center plate) for enabling the user to place foot (feet) thereon and one or more lower layers (underplate plates) that may be placed on a surface of the pedal.

As shown, the plate (housing) may include a number of layers such as

upper plates

1302,1304,1306,1308 and acenter plate1310 for facilitating the user to place his/her feet thereon. The upper plates may then be affixed to one of two underplates, such as anunderplate1312 and anunderplate1314, using plate position adjustment screws (as shown inFIG. 14). Theunderplate1312 and theunderplate1314 may collectively be referred to as ‘underplates’. The positions of the upper plates may be adjusted in and out along

plate adjustment grooves

1316,1318,1320 and1322 located in the underplates. The underplates may be moved closer together or further apart with anadjustable underplate1324 that may be a part of1312. Theadjustable underplate1324 may allow theunderplate1312 to move in and out of theunderplate1314. The position of the underplates may be fixed using a width adjuster.

Further, the plurality of sensors may be attached to the underside of the

underplates

1312 and1314. The plurality of sensors may include asensor1326, asensor1328, asensor1330, a sensor1332 and a sensor1334 (hereinafter may be referred to as the ‘sensors’). Further, a rechargeable power source1336 (such as a battery), aplate circuit board1338 and

strap linkages

1340,1342,1344, and1346 may also be attached to the underside of the underplate. Theplate circuit board1338 may be connected to thepower source1336 and to the sensors.

The sensors may measure data, such as speed, force/pressure applied by the user on the pedal plate (the housing placed on the pedal of the exercise apparatus), based on one or more activities of the user on the pedal plate. For example, one or more pressure sensors may be placed between the multiple layers. The pressure sensors (such as piezoelectric sensors) may capture a change in the pressure, applied by the user, when the multiple layers are compressed between the user's foot and the pedal. Theplate circuit board1338 may collect the data from the sensors (hereinafter may be referred to as ‘sensor data’) and transmits the sensor data via radio frequency to a data processor of an external device, such as a personal computer, a laptop, mobile device (e.g., smartphone) and the like. Theplate circuit board1338 may include aUSB port1348.

The sensors andplate circuit board1338 may be powered by an independent power source, such as arechargeable lithium battery1336. Thebattery1336 may be recharged via aUSB plug1348 that is attached to theplate circuit board1338 which in turn directs energy towards thebattery1336. In an embodiment, power may also be energy that may be harvested from alternative forms of battery and energy such as micro solar panels, kinetic movement and/or pressure applied (by the user) to the pedal.

It may be appreciated by a person skilled in the art that all sources of energy may be viable but it is important that associated methods used for harvesting power do not detract from the users experience or cardio machine's performance. A sensor system implemented by the sensor device by utilizing a power source through a wireless means. The power through the wireless means may be because of the physical moving nature of the pedal plate of the sensor device (sensor system) and the importance of preventing potential for damage to the wires or even user injury through entanglement in the wires.

The sensor device (having pedal plate) may include a system to transmit the sensor data wireless to a remotely located receiver. This may use a range of possible technologies including, but are not limited to, radio frequency, blue tooth and infrared. The receiver may have a transceiver that may receive the sensor data from the pedal plate (e.g. a USB plugged into a nearby PC, laptop or similar). The transceiver may then present the data to the software that uses the pedal plate data. Alternatively, the system may rely on Bluetooth or similar type of technology.

The sensor system (corresponding to the sensor device) may also include a small interim transceiver that may be placed closed to the pedal plate, such as thepedal plate1300. This interim transceiver may both receive the wireless data sent by the pedal plates and then on-sends it, wireless or via wired transmission, to the host device housing the software that may use the sensor data received from the pedal plate. The benefit of the interim transceiver is that it makes the pedal plate design for data transmission easier (closer distance, low energy consumption, line of sight option, etc). This small transceiver may also apply extra processing of the pedal data before on sending further and thus reduce the technical complexity (and energy needs) of the pedal plate.

FIG. 14 illustrates a sensor device depicting the top side of the pedal plate in accordance with some embodiments of the present disclosure. The top side of the pedal plate may be understood more clearly when read in conjunction withFIG. 13 that depicts underside of the pedal plate of the sensor device. The

upper plates

1302,1304,1306,1308 andcenter plate1310 may be of a very hard material like steel or aluminium or hard plastic or a combination or similar. The hard material of the plates may enhance tolerance to bear a huge pressure that may be exerted by a user of an exercise apparatus. The upper surface of the upper plates may incorporate non-slip qualities (e.g. rubberized paint covering or similar effect).

The position of the upper plates may be adjusted to help enable the overall plate shape and size closely match with the pedal shape or size on to which the plates are being placed. As described previously in conjunction withFIG. 13, the adjustment of the upper plates may be by moving the plates along

adjustment grooves

1316,1318,1320 and1322 located in the underplates as illustrated inFIG. 13. Once the plates are in position that may be fixed using plate position adjustment screws1402,1404,1406,1408, the user may use the pedal plates for performing fitness activities on the exercise apparatus. The

underplates

1312 and1314 may also have a non-slip covering on the top side.

Besides the non-slip benefit, this covering may also have a degree of absorption flex, like a rubber layer. This may allow the upper plates to slightly embed themselves into the underplate surfaces when the upper

plate position adjusters

1402,1404,1406 and1408 are tightened. This may help to prevent upper plate slip and also helps the upper plates and underplates to merge more closely into a single surface for users to place their feet thereon.

FIG. 15 illustrates a side view of peizo-based sensors that connects to the pedal plate in accordance with some embodiments of the present invention. Specifically, a side view of sensors attached to an underplate of sensor device is depicted. The sensor device may measure information (hereinafter may be referred to as ‘sensor data’) corresponding to a user's activities performed on a pedal plate of the sensor device.

The sensor data may be a combination of pressure (force applied) and, potentially, movement (e.g., cadence) of the user on the pedal plate (on the exercise apparatus). The combination of force and movement may provide the necessary speed data or at least change in speed to enable software to reasonably accurately adjust for changing effort/speed of the user. In the case of a cadence, the peak and trough pattern of pressure may also be used by the software to identify when a full rotation has occurred. Alternatively, an additional independent movement sensor may be used, like an accelerometer. The benefit of analyzing the changing pressure is that no further sensors are needed and thus saving cost and preserving energy. The benefit of using an independent movement sensor like an accelerometer is increased accuracy/reliability and simpler software.

The pressure sensing system may use a range of standard pressure sensing technologies. In an instance, piezo based sensors may be used, one for each corner of the plate and one in the center of the plate (as shown inFIG. 13). However, alternative sensor arrays may achieve the same function. The important point is that a number of sensors may be needed to ensure that all the pressure applied to the pedal plate is captured even if the foot is placed only on a part of the pedal surface.

As shown, in an embodiment, the sensors in our example comprise two layers: apiezo sensor layer1502 that may be fixed underneath an underplate, such as theunderplate1312 or the underplate1314 (as depicted inFIG. 13) and may incorporate a hole through the center of it. The second layer may be a sensormetal base layer1504. The sensormetal base layer1504 may be in direct contact with the surface of the pedal of the exercise apparatus. The sensormetal base layer1504 may have acolumn1506 in the center thereof. Thecolumn1506 may go through the hole of thepiezo sensor layer1502 and into a cavity1508 just above thepiezo sensor layer1502. The top of thecolumn1506 where it is inside the cavity1508, thecolumn1506 may widen out much like the head of a nail.

Thecolumn1506 and the cavity1508 may enable the sensormetal base layer1504 to have a tiny amount of movement latitude relative to the rest of the plate items which are fixed together. This movement latitude may allow the pressure exerted by thepiezo sensor layer1502 that may be in direct contact with the sensormetal base layer1504 to vary. It is this variance that may be measured by the piezo sensor. Data comprising the total variance of all the sensors may be used to calculate the total pressure being applied by the user to the pedal. Each sensor may be attached by awire1510 to theplate circuit board1338 shown inFIG. 13.

Reference is now made toFIG. 16 that shows an underside view of the piezo-based sensor that may be utilized for the pedal plate in accordance with some embodiments of the present invention. The underside view of the piezo-based sensor may be understood more clearly when read in conjunction withFIG. 15. As shown, the circumference of themetal base layer1504 of the piezo-based sensor may be marginally smaller than the circumference of thepiezo sensor layer1502 as illustrated by the underside view of sensors inFIG. 16. This ensures that the entire downward force that may ultimately be taken by the sensor metal base plates (metal base layer1504) such as is fully captured by the piezo sensor area (i.e., piezo sensor layer1502).

An alternative to the piezo sensor technology may be a system of interconnected compressible chambers containing fluid (hereinafter may be referred to as ‘liquid chambers’) and may be connected to a liquid pressure sensor. The chambers may be placed in between multiple layers of the pedal plate. As downward pressure may be applied via the underplate, the multiple layers may press upon the chambers forcing the liquid to exert pressure on the connected liquid pressure sensor.

Further, it may be appreciated by a person skilled in the art that functioning of the sensor system (sensor device) is not restricted to usage of piezo-based sensor or a liquid sensor. Further, a plurality of sensors may be utilized based on a requirement for measuring various parameters associated with the force and motion applied by the user on the pedal plate of the sensor device.

FIG. 17 illustrates an implementation of the sensor device utilizing a pedal plate in accordance with some embodiments of the present disclosure. Specifically,FIG. 17 depicts a plate-type structure (housing, as explained previously in conjunction withFIG. 13) on top of a pedal (of an exercise apparatus) with a foot placed on top of the plate and straps that hold the plate onto the pedal. The plate may be attached to the pedal by any one of a variety of means depending on circumstances and pedal attributes.

As shown, in an embodiment, the design assumes stretchy

robust material straps

1702,1704 that may connect to four

strap linkages

1340,1342,1344 and1346 (shown inFIG. 12) placed on underplates, such as the

underplates

1312,1314. These may include, but are not restricted to, (i) micro Velcro pads attached to each side with adhesive (ii) a stretchable fabric into which the plates may be inserted and the fabric may then be wrapped around the pedal like a sock (iii) tiny plates that may be fitted and able to clamp on the vertical edges and then may provide a means for connecting with the plate.

The material straps1702 and1704 may join at thestrap underside1706 that may be on the opposite side to the side with the plate. Thestrap underside1706 may include a counterweight of sorts that can help to maintain any original intended pedal weight equilibrium (e.g., one side of the pedal is designed through weight distribution to always be facing upwards). Thestrap underside1706 or other areas of the strap may also support some of the components shown in the diagrams as being in the plate. For example, the battery and USB connection may be house somewhere within the straps that fix the plate to the pedal. This may help to minimize the required size of the plate and may provide natural counter balance for the pedal.

Further, sensors, such as the

sensors

1326,1328,1330,1332, and1334 (as shown inFIG. 13) may be embedded below the under plates. As shown, inFIG. 17, the sensor1326 (and others sensors) may be placed below the under

plates

1312 and1314 that are placed below upper plates, such as the

upper plates

1302,1304,1306 and1308. The plate-structure (including sensors) may be placed above apedal1708 of the exercise apparatus (as shown by a rotatingaxel1710 for linking thepedal1708 with the exercise apparatus).

As shown, afoot1712 of the user may be placed on the plate (on theupper plates1312 and1314) that may be linked to the pedal. The movement (speed) and/or force (pressure) applied by the user may be measured by the sensors, such as thesensor1326. The measured data may be transmitted throughradio signal1714 from a circuit board of the plate to an external device. The external device may have aradio frequency transceiver1716 to receive theradio signals1714 corresponding to the measured sensor data that may be utilized further based on the requirement. For example, the received data may be analyzed to determine fitness status of the user.

FIG. 18 illustrates a flow chart of a method of power management in accordance with an embodiment of the present disclosure. The power management in a sensor system while determining a plurality of characteristics of a user's activities on an exercise apparatus may be understood more clearly when read in conjunction withFIG. 6. The order in which the method is performed is not intended to be construed as limitation, and further any number of the method steps may be combined in order to implement the method or an alternative method without departing from the scope of this disclosure.

Atstep1802, it is determined that If there is an external (USB) power source is available to provide power to the sensor device. If no external (USB) power source is available then the method may proceed to step1804 (as shown by ‘No’ pointer from step1802). Atstep1804, the core chip of the sensor device may rely on lithium battery and may receive power from the lithium battery power circuit boards. Further, if the lithium battery is being used, the core chip will lower the operating frequency of the system to help extend the life of the battery before recharge is needed. An LED light may also be added to Circuit Board to detect when the battery output is below 3.6V (i.e. it needs to be recharged).

Further, If atstep1802, it is determined that a USB is connected as an external power source, then the method may proceed to step1806 (as shown by ‘Yes’ pointer from step1802) to determine if lithium battery is also connected. If, atstep1806, the presence of lithium battery is determined (as shown by ‘Yes’ pointer from step1806), it depicts that both the sources (USB and lithium batteries) are present and accordingly the core chip may use the external (USB) power source to both power the circuit boards and recharge the lithium battery. Further, if, atstep1806, it is determined that the lithium battery is not connected (as shown by ‘Yes’ pointer from step1806), then USB power source may be utilized for powering the system.

Further, the method implemented by the sensor device is not restricted to above mentioned embodiment of power management, as mentioned herein. Further, various embodiments that are explained inFIGS. 1 to 17 may be utilized to implement various method steps to carry out processes that may be implemented by the sensor device (sensor system) as explained here above. Further, the invention is not limited to above-mentioned embodiments and examples and many other embodiments and examples may be implemented in light of the invention without departing from the scope of the invention.

Advantageously, the present disclosure provides a fitness equipment sensor device and a system for determining various parameters corresponding to user's activities on an exercise apparatus. Such parameters may be used further for various other applications such as, but not limited to, providing interactive interface, entertainment, determining fitness status of a user and so on. The sensor device does not require any special fitting to receive information corresponding to the user using the exercise apparatus. In one embodiment, the sensor device may use wheel mechanism for the exercise apparatuses having a tread surface (such as treadmill). Due to usage of wheel mechanism, the sensor device provides cheap, simple and reliable solutions. Further, embodiments of the present disclosure provide a sensor device that may be utilized for exercise apparatuses having pedals system, such as cycles, rowers and the like. The information corresponding to the user may include, but is not limited to, user's speed (and therefore stride, when combined with information related to speed), and force applied on the exercise apparatus.

An additional advantageous feature of the sensor device is that the device can work with any kind of treadmill regardless of age, brand, size or design. All treadmills will have a section of the tread exposed on the underside when the treadmill is in its ready-for-use position. The one variable is the height of the underside tread from the ground and the level of variation in height while in use. To accommodate this, a mechanical system may be applied that enables the device's wheels to maintain contact with the exposed underside tread.

Further, to provide accuracy in determining the user's information, the sensor device for exercise apparatuses such as treadmills may uses magnets in the wheels that may passes by hall switches to determine data per revolution of the wheels more accurately.

In various embodiments of the present disclosure, the sensor device may implement a system to process the information measured by the sensor device (‘sensor data’) prior to transmitting the information to another device for further usage thereof. Also, the sensor device may implement a method for power management that may utilize rechargeable battery system. Further, the sensor device may implement a system for harvesting energy from various ways that may provide prolong energy source for the system. For example, the system may utilize kinetic energy from the user's motion on the exercise apparatus.

Further, the system may use magnets in a rotating wheel to measure speed that may allow the magnetic energy to be harvested for energy purposes. Further, brushless rotor motor may also be attached to a small wheel to ensure decent rotations speed. Alternatively, new technologies that can harvest energy from motion like “reverse electrowetting” or variants thereof may be applied. However, in all instances, the level of energy harvested may be balanced against the total force applied to the treadmill surface which may otherwise interfere with the treadmills performance.

It may be appreciated by a person skilled in the art that the present invention is not limited to the above-mentioned embodiments. Further, various other embodiments may also be implemented through the features provided by the system. Also, the usage of terminology such as ‘first user’, ‘second user’ may not be considered a restrictive aspect of the present invention as such terminologies are used just for the purpose of better explanation. It may be appreciated by a person skilled in the art that the invention is not limited to the advantages as mentioned here above. Further many other advantages may be understood in light of the description given above without departing from the scope of the invention.

The foregoing description, for purpose of explanation, has been described with reference to specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many modifications and variations are possible in view of the above teachings. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated.

Embodiments of the invention are described above with reference to block diagrams and schematic illustrations of methods and systems according to embodiments of the invention. It will be understood that each block of the diagrams and combinations of blocks in the diagrams can be implemented by computer program instructions. These computer program instructions may be loaded onto one or more general purpose computers, special purpose computers, or other programmable data processing translator to produce machines, such that the instructions that execute on the computers or other programmable data processing translators create means for implementing the functions specified in the block or blocks. Such computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means that implement the function specified in the block or blocks.

While the invention has been described in connection with what is presently considered to be the most practical and various embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. The invention has been described in the general context of computing devices, phone and computer-executable instructions, such as program modules, being executed by a computer. Generally, program modules include routines, programs, characters, components, data structures, etc., that perform particular tasks or implement particular abstract data types. A person skilled in the art will appreciate that the invention may be practiced with other computer system configurations, including hand-held devices, multiprocessor systems, microprocessor-based or programmable consumer electronics, network PCs, minicomputers, mainframe computers, and the like. Further, the invention may also be practiced in distributed computing worlds where tasks are performed by remote processing devices that are linked through a communications network. In a distributed computing world, program modules may be located in both local and remote memory storage devices.

This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined in the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.

Claims

1. A sensor system for collecting user activity data from an exercise apparatus, the sensor system comprising:

a wheel mechanism for measuring a plurality of characteristics corresponding to a moving tread of the exercise apparatus, wherein the wheel mechanism is in physical contact with the moving tread, without having to be fastened to the exercise apparatus;

a plurality of sensors configured for determining a plurality of parameters corresponding to one or more activities performed by a user of the exercise apparatus, the plurality of parameters being determined based on the measured plurality of characteristics of the moving tread; and

a data communication interface for transmitting the measured plurality of parameters to a data processor,

wherein the physical contact between the wheel mechanism and the moving tread is maintained by a spring-based mechanism.

2. The sensor system ofclaim 1, wherein the wheel mechanism comprises a primary wheel and a secondary wheel, the primary wheel being utilized for measuring a speed of the moving tread and the secondary wheel being utilized for measuring tilt of the moving tread in conjunction with the primary wheel.

3. The sensor system ofclaim 1, wherein the plurality of parameters comprises speed of the user, downward pressure applied to the moving tread by the user, and the one or more activities of the user on the moving tread.

4. The sensor system ofclaim 1 further comprising:

a power source for powering the plurality of sensors and the data communication interface; and

a circuit board for managing the power sources, the plurality of parameters and the data communication interface.

5. The sensor system ofclaim 2, wherein the primary wheel comprises a series of magnets adjoined thereto, the series of magnets being utilized to interface with a magnetic based sensor, of the plurality of sensors, for measuring rotation of the primary wheel.

6. The sensor system ofclaim 2, wherein the primary wheel incorporates a regular pattern of grooves, and wherein an LED light and LED sensor are used to measure the rotation of the primary wheel through the grooves.

7. The sensor system ofclaim 2, wherein the primary wheel comprises a pattern of reflective surfaces and a sensor for counting changes in surface reflection for measuring the rotation of the primary wheel.

8. The sensor system ofclaim 1, wherein the plurality of sensors comprises a rotation sensor attached to an axis of the primary wheel for measuring a rotation speed of the wheel.

9. The sensor system ofclaim 1, wherein the plurality of sensors comprises a piezoelectric sensor for measuring downward pressure exerted towards floor by the exercise apparatus, the piezoelectric sensor being placed under a load bearing point of the exercise apparatus.

10. The sensor system ofclaim 1, wherein an infrared sensor is placed alongside the exercise apparatus for capturing data about the user's activity when moving on the exercise apparatus.

11. The sensor system ofclaim 10, wherein a monochrome CMOS sensor is used to enhance an effectiveness of the infrared sensor.

12. The sensor system ofclaim 1 further comprising a camera pointed at the moving tread of the exercise apparatus, the camera being used to capture data about the user's activity when moving on the exercise apparatus.

13. The sensor system ofclaim 1, wherein the wheel mechanism comprises a primary arm and a secondary arm corresponding to a primary wheel and a secondary wheel of the wheel mechanism, the spring-based mechanism corresponds to the primary arm and the secondary arm to force at least one of the primary wheel and the secondary wheel in upward direction towards the tread of the exercise apparatus.

14. The sensor system ofclaim 13, wherein the wheel mechanism maintains the secondary arm at a constant angle range relative to a horizontal line and irrespective of the primary arm's angle relative to the horizontal line.

15. The sensor system ofclaim 13, wherein the upward force exerted through a spring-based mechanism linked to the secondary arm is independent of the spring based force exerted on the primary arm connected to the secondary arm.

16. The sensor system ofclaim 1, wherein the data communication interface comprises a transceiver and utilizes at least one of a wireless and a wired data transmission technology to transmit the measured plurality of parameters to the data processor.

17. The sensor system ofclaim 4, wherein the power source is a lithium battery, the battery is rechargeable.

18. The sensor system ofclaim 4, wherein the power source is managed by a protocol for utilizing power from the wired connection when power from both a wired connection and a battery source are detected as available, and wherein unused power from the wired connection is utilized for recharging the battery source.

19. The sensor system ofclaim 4, wherein the power source is managed by a protocol to reduce power consumption by lowering an operating cycle of the circuit board when the power source is a battery.

20. The sensor system ofclaim 4, wherein the power source corresponds to harvested renewable sources comprising at least one of solar panels and the kinetic energy generated by at least one of the exercise apparatus and the activities of the user on the exercise apparatus, and wherein the renewable sources are used for at least one of supplying power and recharging a battery.

21. A sensor device for collecting user activity data from an exercise apparatus without requiring access to mechanics of the exercise apparatus, the sensor device comprising:

a housing comprising multiple layers containing a plurality of sensors, a circuit board and a power source, the housing being attached to a pedal of the exercise apparatus,

the plurality of sensors configured for measuring one or more parameters corresponding to one or more activities performed by a user on the pedal of the exercise apparatus; and

a data communication interface coupled to the circuit board, the data communication interface configured for transmitting the measured parameters to a data processor.

22. The sensor device ofclaim 21, wherein the one or more parameters comprises at least one of pressure applied to the pedal and motion of the pedal.

23. The sensor device ofclaim 21 wherein the multiple layers comprise:

one or more upper layers for enabling the user to place foot thereon; and

one or more lower layers placed on a surface of the pedal.

24. The sensor device ofclaim 21 further comprising:

a power source for powering the sensors and the data communication interface; and

a board-based electrical circuit for managing the power sources, sensor data and data communication interface.

25. The sensor device ofclaim 21, wherein the housing is of a plate-type structure, the plate-type structure being adjustable based on an original surface area of the pedal.

26. The sensor device ofclaim 21, wherein the circuit board and battery are designed and housed in a manner to remain isolated from a pressure applied by the user's foot.

27. The sensor device ofclaim 21, wherein one or more pressure sensors are placed between the multiple layers, the one or more pressure sensors configured to capture a change in a pressure when the multiple layers are compressed between the user's foot and the pedal.

28. The sensor device ofclaim 21 comprises one or more piezoelectric sensors.

29. The sensor device ofclaim 21 further comprising a series of interconnected compressible chambers containing liquid and connected up to a liquid pressure sensor, the chambers being placed in between the multiple layers, wherein on applying the pressure, the multiple layers press upon the chambers forcing the liquid to exert pressure on the connected liquid pressure sensor.

30. The sensor device inclaim 21 wherein the plurality of sensors comprise at least one accelerometer-type sensor for providing data about motion of the pedal.

31. The sensor device ofclaim 21, wherein the data communication interface comprises a transceiver and utilizes at least one of a wireless and a wired data transmission technology to transmit the measured plurality of parameters to the data processor.

32. The sensor device inclaim 24, wherein the power source is a rechargeable lithium battery for providing power for one or more operations of the sensor device.

33. The sensor device inclaim 24, wherein the power source is managed by a protocol for utilizing power from the wired connection when power from both a wired connection and a battery source are detected as available, and wherein unused power from the wired connection is utilized for recharging the battery source.

34. The sensor device ofclaim 24, wherein the power source is a wired connection and utilized via one of USB connection using USB HID protocol and an external plug.

35. The sensor device inclaim 24, wherein the power source is managed by a protocol to reduce power consumption by lowering an operating cycle of the circuit board when the power source is a battery.

36. The sensor device inclaim 24 wherein the power source corresponds to harvested renewable sources comprising of at least one of solar panels and kinetic energy generated by a force applied by the user to the pedal, wherein the renewable sources are used for at least one of supplying power to the sensor device and recharging the battery.

37. The sensor device ofclaim 21 further comprising a mechanism for preventing slippage of the user from the housing placed over the pedal of the exercise apparatus.

38. The sensor device ofclaim 21 further comprising a system to attach the housing to the pedal, the system includes counterweights placed on an opposite side to the multiple layers to provide the pedal with a counter weight to maintain a pedal balance.

39. The sensor device ofclaim 38, wherein the system to attach the housing to the pedal includes brackets for locking around one or more edges of the pedal, the brackets allow attaching and detaching the plurality of sensors contained by the housing.

40. The sensor device ofclaim 21, wherein small plates are attached with an adhesive to a surface of the pedal allowing attaching and detaching of the housing.