US20120115685A1 - Exercise apparatus with automatically adjustable foot motion - Google Patents

Abstract

An elliptical exercise apparatus includes a frame, a pair of footpads, and a linkage coupling the footpads to the frame and for guiding the footpads in closed paths when a user's feet apply forces to the footpads. The linkage, which includes a rotatable member having an angular position indicative of the positions of the footpads within their closed paths, responds to input control signals by adjusting length and height dimensions of the closed paths. A control system senses the angular position of the rotatable member, senses the forces the user applies to the footpads, and generates the control signals to increase or decrease the path dimensions when it senses particular combinations of angular position and user forces, thereby permitting the user to control the path dimensions by controlling the forces applied to the footpads.

Description

BACKGROUND OF THE INVENTION
• 1. Field of the Invention
• The present invention relates to exercise apparatus, and more specifically to an exercise apparatus that guides a user's feet through automatically adjustable paths of motion.
• 2. Description of Related Art
• Running on treadmills remains a popular form of indoor aerobic exercise even though it can lead to injuries. A runner hops from foot-to-foot, stressing his or her lower extremities with repetitive impact forces of each footfall that can eventually injure joints and tendons. Running the equivalent of only ten miles per day on a treadmill can expose each leg to 200,000 impacts per year. Many other kinds of exercise apparatus, including stationary bicycles, steppers, climbers, gliders and skiers, provide indoor aerobic exercise that allow a user's feet to follow a closed path without the impact stress associated with treadmills, however despite the advantages of these apparatus, running on treadmills remains popular. Since people are structurally better adapted to run rather than to pedal, climb steps, glide or ski, they often feel more comfortable running.
• Elliptical exercise apparatus include foot support or pedals following closed paths designed to mimic the non-circular paths a user's feet trace out when running on a treadmill, but since the user's feet do not leave the foot supports, the user can engage in a running style of exercise without experiencing the repetitive impacts associated with running on a treadmill. Since the user's feet follow paths that are neither linear nor circular, they are commonly called “elliptical” paths to distinguish them over the circular closed paths provided stationary bicycle apparatus and the linear or arcuate closed paths associated with steppers and skier, gliders and climbers, even though an elliptical exercise apparatus normally does not provide a truly elliptical foot path.
• A typical elliptical exercise apparatus includes a crank moving in a circular motion and a linkage mechanism coupling the crank to its foot supports for converting the circular motion of the crank into the “elliptical” motion of the foot supports. The linkage also includes a resistance device such as a regenerative or eddy current brake coupled to the crank for providing an adjustable resistance to the foot motion for controlling the amount of work the user must expend to move the foot supports. Examples of elliptical exercise apparatus are disclosed in U.S. Pat. No. 4,185,622 to Swenson; U.S. Pat. No. 5,278,529 to Eschenbach, U.S. Pat. No. 5,383,829 to Miller; U.S. Pat. No. 5,540,637 to Rodgers, Jr.; U.S. Pat. No. 6,196,948 to Stearns et al.; and U.S. Pat. No. 6,468,184 to Lee, all of which are incorporated herein by reference.
• The height and length of a runner's stride varies depending on running speed, on the terrain and on the runner's preferences. While early elliptical exercise apparatus designs allowed a user to engage in a running style of motion while avoiding the impact stress associated with treadmills, the shape of the path the user's foot followed was fixed and the user was not able to adjust either the height or length of stride. Later elliptical exercise apparatus designs allowed a user to adjust stride length. For example U.S. Pat. No. 5,893,820 issued Apr. 13, 1999 to Maresh et al. describes an elliptical apparatus allowing a user to adjust the shape of an elliptical footpath by manually changing the linkage between the crank and the foot supports. U.S. Pat. No. 5,919,118 issued Jul. 6, 1999 to Stearns et al. teaches to incorporate a linear actuator into the linkage that can expand or contract to change the shape of the linkage in response to a signal controlled by a user-operable button on a control panel, thereby to change stride length. Although these apparatuses allow a user to adjust stride length, they required the user to stop the apparatus and manually alter the linkage, or to operate a control knob or button while exercising, either of which is inconvenient.
• Still later designed elliptical exercise apparatuses automatically adjust stride length or height. U.S. Pat. No. 6,206,804 issued Mar. 27, 2001 to Maresh describes an elliptical exercise including dampers or springs in the linkage assembly defining the user's footpath that automatically vary the path shape in response to forces applied by the user's foot. U.S. patent application 20050181911, filed Aug. 18, 2005 by Porth teaches an elliptical exercise apparatus that senses the speed at which the crank rotates in which the crank rotates and adjusts an actuator in the linkage so that both stride length and height change with speed and pedaling direction. While the apparatus automatically adjusts stride length or height, there is no assurance that stride length or height that is adjusted as a function of speed or direction will match the user's desired stride length or height.
SUMMARY OF THE INVENTION
• An elliptical exercise apparatus in accordance with the invention includes frame, a pair of footpads for supporting the user's feet, and a linkage coupling the footpads to the frame for guiding the footpads in a closed paths when the user's feet apply forces to the footpads. The linkage includes actuators that respond to control signals by adjusting length and height dimensions of the closed paths. The linkage also includes a rotatable member having an angular position that is indicative of the positions of the footpads within their closed paths.
• The exercise apparatus further includes a control system that senses the angular position of the rotatable member and, for each footpad, senses the forces applied to the footpad and generates the control signals for controlling the length and height dimensions of the closed path as functions of the sensed angular position and forces. The control system increases or decreases the length and height dimensions of the closed path of each footpad when the user-applied force on the footpad is outside a particular magnitude range while the angular position of the rotatable member is within a particular angular position range. The exercise apparatus thus enables the user to independently control stride height and length of each footpad by controlling magnitudes of the forces the user applies to each footpad as it passes through a particular section of its closed path.
• In one embodiment of the invention, the control system includes strain gauges attached to the footpads that sense user applied forces. In another embodiment of the invention, the controller determines user applied forces as functions of the acceleration of the rotatable member.
• The claims appended to this specification particularly point out and distinctly claim the subject matter of the invention. However those skilled in the art will best understand both the organization and method of operation of what the applicants consider to be the best modes of practicing the invention by reading the remaining portions of the specification in view of the accompanying drawings, wherein like reference characters refer to like element
BRIEF DESCRIPTION OF THE DRAWING
• FIG. 1 is a perspective view an exercise apparatus constructed according to the principles of the present invention.
• FIGS. 2A and 2B are perspective views of a footpad of the exercise apparatus ofFIG. 2.
• FIG. 3 is a left side elevation view of the exercise apparatus ofFIG. 1.
• FIGS. 4 and 5 are perspective views of alternative versions of a crank assembly for the exercise apparatus ofFIG. 1.
• FIGS. 6A-6D are simplified side elevations views of portions of the exercise apparatus ofFIG. 1.
• FIG. 7 is a block diagram an exercise control, monitoring and display system for the exercise apparatus ofFIG. 1.
• FIG. 8 is a plan view of the control panel ofFIG. 1.
• FIG. 9 is a diagram defining position of the crank member ofFIG. 1.
• FIG. 10 depicts a software routine executed by the computer ofFIG. 7 for automatically controlling stride length.
• FIG. 11 depicts a software routine executed by the computer ofFIG. 7 for automatically controlling stride height.
• FIG. 12 graphically depicts the angular velocity and acceleration of the crank member of the apparatus ofFIG. 1 as functions of angular position.
• FIG. 13 is a block diagram depicting a subcircuit of I/O circuit118 ofFIG. 7.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
• The present invention may be implemented in connection with exercise apparatus having a frame, user-operable footpads and a linkage for coupling the footpads to the frame and for guiding the footpads in closed paths. The invention relates in particular to a method for automatically responding to user forces applied to the footpads by adjusting one or more dimensions of the closed path each foot support follows. Although the invention is illustrated below as being used to control path dimensions in an elliptical exercise machine, the invention may be used to control path dimensions in other types of exercise machines having adjustable path dimensions. Although there are many possible modes of practicing the invention defined by the claims appended to this specification, the following specification and drawings describe in detail only preferred embodiments of practicing the invention. Since not all implementation details described below are necessary to practice the invention as recited in the claims, it is intended that the invention be limited only by the claims.
Mechanical System
• FIGS. 1-5 depict anelliptical exercise apparatus10 in accordance with the invention including aframe14, aleft footpad50 and aright footpad51 for supporting a user's left and right feet. Left andright linkage assemblies22 and23 for a linkage for coupling the left andright footpads50 and51 to frame14 and for guiding the footpads in closed paths when the user's feet apply forces to the footpads. As discussed below, eachlinkage assembly22 and23 includes actuators that respond to control signals by adjusting length and height dimensions of the closed path its corresponding footpad follows. Each linkage assembly also includes a rotatable member, suitably acrank member12 rotatably mounted on aframe14, having an angular position that is indicative of the positions of the footpads within their closed paths. A control system, including acontrol panel24 mounted onframe14, senses the angular position of the rotatable member and, for each footpad, senses the forces applied to the footpad and generates the control signals for controlling the length and/or height dimensions of the closed path as functions of the sensed angular position and forces. The control system increases or decreases the length and height dimensions of the closed path of a footpad when the user-applied force on the footpad is outside a particular magnitude range while the angular position of the rotatable member is within a particular angular position range.Exercise apparatus10 thus allows the user to control stride height and length by controlling magnitudes of the forces the user applies to the footpads as they pass though particular sections of their closed paths.
• Left linkage assembly22 also includes a telescopingleft foot member16 having anupper channel member18 supportingleft footpad50 and slidably engaging alower channel member20.Left linkage assembly22 further includes an adjustable length crankassembly26 pivotally couplinglower channel member20 to crankmember12, aleft rocker arm28 pivotally coupled to frame14 through abearing pin30 and pivotally coupled toupper channel member18 through abearing pin32, a leftlinear actuator34 attached torocker arm28, and aleft drawbar36 pivotally coupled to crankmember12 andlower channel member20 through bearingpin26 and pivotally coupled toactuator34 through abearing pin38. An upper end ofrocker arm28 forms ahandlebar40.
• Right linkage assembly23 is generally similar toleft linkage assembly22 and includes a telescopingright foot member17 for supporting theright footpad51, aright side actuator35 similar toleft side actuator34.
• In addition to the right and leftlinkage assemblies22 and23, the linkage also includes aregenerative brake46 mounted insideframe housing48 and acrank member12 connected through abelt44 to the regenerative brake's rotor that rotates withcrank member12.Brake46 provides an amount of resistance to crank member rotation that is adjusted by a control signal fromcontrol panel24.
• As shown inFIGS. 2A and 2B, leftfootpad50, includes a set ofrollers52 for rollably engagingupper channel member18 and aflexible hook member54 for grasping anupright member56 attached to an upper channel member for limiting horizontal motion offootpad50 alongupper channel member18. Astrain gauge58 mounted onhook member54supplies control panel24 with an indicating signal of magnitude that varies ashook member54 flexes. Strain gauge is58 is biased so that its output signal magnitude is at a maximum when a user forces footpad50 to the most forward position (toward rocker link28) alongchannel member18 allowed byhook member54 and is at a minimum when the user forces footpad50 the most rearward position (toward crank member12) alongchannel member18 allowed byflexible hook member54. The magnitude of the output signal ofstrain gauge58 is a measure of the horizontal force a user applies to footpad50.Footpad50 flexes as the user applies a downward force on the footpad, and anotherstrain gauge60, attached to the underside offootpad50, providescontrol panel24 with an output signal of magnitude that varies with the amount by whichfootpad50 flexes. Thus the output signal ofstrain gauge60 is a measure of the magnitude of the downward-directed vertical force a user applies to footpad60. Flexible conductors (not shown) convey the output signals ofstrain gauges58 and60 to controlpanel24.Right footpad51 is similar toleft footpad50 and includes similar strain gauges.
• FIG. 4 depicts an example implementation of left side adjustable crankassembly26 as including alinear actuator62 attached to crankmember12 for adjustably controlling a distance between acrank rod64 and the crank member'srotational axis66. Crankrod64 is coupled through bearings to footpadlower member20 anddrawbar36.Linear actuator62 includes a stepper motor controlled by signals fromcontrol panel24 that are delivered to the stepper motor through wirescoupling control panel24 to brush contacts (not shown) on crankmember12. A similar adjustable crank assembly, including alinear actuator63 is mounted on the right side ofcrank member12 to form a portion of leftside linkage assembly23 ofFIG. 1.
• FIG. 5 shows an alternative version of left crankassembly26 including alinear actuator68 pinned to crankmember12 for adjustably rotating alever arm70 also rotatably pinned to crankmember12, thereby to adjust the distance between crankrod64 attached tolevel arm70 and crank memberrotational axis66.Linear actuator68 includes a stepper motor controlled by signals fromcontrol panel24 that are delivered to the stepper motor through wirescoupling control panel24 to brush contacts (not shown) on crankmember12. A similar adjustable right crank assembly mounted on the right side ofcrank member12 forms a portion of rightside linkage assembly23 ofFIG. 1.
Elliptical Motion
• A user standing onright footpad50 applies forces to footpad50 andhandlebar40 that causefoot member16 to follow an elliptical path defined bylinkage assembly22 andcause handlebar40 to oscillate about bearingpin30. We refer to the length of the elliptical path in the generally horizontal direction as the “stride length” and refer to the length of the elliptical path in the generally vertical direction as the “stride height”.Actuators34 and62 ofFIGS. 3 and 4 control the stride height and stride length by adjusting the shape of the elliptical path. Theleft side actuators35 and63 similarly control the stride length and stride height of the elliptical path followed byleft footpad51.
• The “crank radius”, the distance betweenpin64 and therotational axis66 ofcrank member12 controlled byactuator62 ofFIG. 4, influences the both stride height and stride height; as the crank radius increases, so too do stride height and stride length, The “rocker radius”, the distance between bearing pins30 and38 controlled bylinear actuator34 also influences stride height but does not substantially influence stride height; as rocker radius increases, stride length decreases.
• FIGS. 6A-6D show four exampleelliptical paths72A-72D followed by a point onleft footpad50. InFIG. 6A, the crank radius is relatively small and rocker radius is relatively long, so both stride height and stride length ofpath72A are small. InFIG. 6B, both crank radius and rocker radius are relatively large, so both stride length and stride and stride ofpath72B are larger than inpath72A. InFIG. 6C, the rocker radius is relatively small and the crank radius is relatively large, so the stride length ofpath72C is longer than inpaths72A and72B and stride height is as large as inpath72B. InFIG. 6D, both rocker radius and crank radius are small, so stride length ofpath72D is long, about the same as forpath72B, but stride height is small, about the same as inpath72A.
• Thus the control system can adjustactuators34 and62 to provide a stride length ranging from the short stride length ofpath72A to the long stride length ofpath72C and to provide a stride height ranging from the short stride height ofpath72A to the high stride height ofpath72C. Although the crank radius controlled byactuator62 influences both stride height and stride length, the control system can independently adjust stride height and stride length. For example, to increase or decrease stride length without affecting stride height, the control system can signalactuator34 to decrease or increase the rocker radius without signalingactuator62 to change crank radius. To increase stride height without affecting stride length, the control system can signalactuator62 to increase the crank radius and can signalactuator34 to increase the rocker radius. The increase in crank radius not only increases stride height, but also tends to increase stride length, the control system can offset the increase in stride length by appropriately increasing rocker radius so that there is no net increase in stride length. Conversely, to decrease stride height without affecting stride length, the control system can signalactuator62 to decrease the crank radius andsignal actuator34 to appropriately decrease the rocker radius.
• As discussed below, whenexercise apparatus10 is in a manual stride height or length adjustment mode, the control system adjusts stride height or length in response to use-operated pushbuttons mounted oncontrol panel24. When theexercise apparatus10 is in an automatic stride height or length adjustment mode, the control system adjusts stride height or length in response to forces the user applies to footpads50 and51 which are sensed bystrain gauges58 and60 ofFIGS. 2A and 2B or by alternative means described below.
Control System
• FIG. 7 is a block diagram showing a control system forexercise apparatus10 ofFIGS. 1-5 including aconventional computer110 residing withincontrol panel24 and an I/O interface circuit118 interfacing computer100 touser input devices112 anddisplay devices114 mounted oncontrol panel24, and anetwork adapter116.User input devices114 allow the user to input commands to computer and may include, for example, pushbuttons, control knobs, a keyboard and/or a touch screen.Display devices114, which may include, for example, pushbutton lights, light emitting diodes, alphanumeric display panels, and/or a video monitor, allowcomputer110 to present various kinds of information to the user.Network adaptor116, which may be wireless, allowscomputer110 to communicate with other computers via conventional network and Internet protocol for uploading programs and downloading or uploading data.
• The control system also includes various sensor and control devices coupled tocomputer110 via I/O interface circuit. Right side control devices andsensors120 includeactuators35 and63 andstrain gauges59 and60. Left side control andsensor devices122 includeactuators34 and62 andstrain gauges58 and60. Strain gauges58-61 produce signals H_FORCE_R, H_FORCE_L, VFORCE_R and VFORCE_L, respectively, indicating the magnitudes of horizontal and vertical forces the user applies to footpads50 and51.
• Regenerative brake46 includes agenerator126 coupled for rotation withcrank member12 ofFIGS. 1-4.Generator126 generates an output voltage across avariable resistor128 that increases with the generator's rotational velocity producing a current throughresistor128.Resistor128 dissipates in the form of heat the rotational energy the user expendsrotating generator126. Under control ofcomputer110, I/O interface118 transmits a signal RESISTANCE toresistor128 that controls the electrical resistance ofresistor128, thereby controlling the mechanical resistanceregenerative brake46 provides to crank rotation. The voltage acrossresistor128 is proportional to the angular velocity of crank rotation and is provided as a VELOCITY signal input to I/O interface circuit118, which includes an analog-to-digital converter for converting the analog VELOCITY signal into digital data input tocomputer110 indicting rotational velocity.
• Anangular position sensor126 mounted withinframe housing48 ofFIG. 1 provides a POSITION signal to I/O interface118 indicating the angular position ofcrank member12. In some embodiments of the invention, the VELOCITY signal may be omitted sincecomputer110 can alternatively compute velocity from changes in angular position indicated by the POSITION signal. Devices and circuits capable of carrying out the interface functions of I/O interface circuit118 are well known to those of ordinary skill in the art.
• Under control ofcomputer110, I/O interface circuit118 transmits control pulses toactuators34,35,62 and63 via the following control signals. Each control signal pulse tells the receiving actuator to increment or decrement its length by a unit amount:
• INC_CR_R to tellactuator35 to increment right side crank radius,
• DEC_CR_R to tellactuator35 to decrement right side crank radius.
• INC_RR_R to tellactuator63 to increment right side rocker radius,
• DEC_RR_R to tellactuator63 to decrement right side rocker radius.
• INC_CR_L to tellactuator34 to increment left side crank radius,
• DEC_CR_L to tellactuator34 to decrement left side crank radius,
• INC_RR_L to tellleft actuator62 to increment left side rocker radius, and
• DEC_RR_L to tellactuator62 to decrement left side rocker radius.
• Actuators34,35,62 and63 include internal limit switches to preventcomputer110 from signaling them to drive rocker radius or crank radius beyond their maximum or minimum limits. During system startup,computer110 sends a sufficient number of pulses to each actuator to ensure that crank radius is at a minimum and rocker radius is at a maximum. Thereafter,computer110 keeps track of the number of increment and decrement pulses it sends to each actuator in order to keep track of each crank and rocker radius.Computer110 maintains a lookup table in its memory that relates crank and rocker radius to stride length and stride height. Whenevercomputer110 needs to increment or decrement stride height or stride length, it uses the lookup table to determine the amount by which it must increment or decrement rocker radius and/or crank radius in order to achieve the desired change in stride height or length.
Stride Length Adjustment
• The user can commandcomputer110 to operate in either a manual stride length adjustment mode whereincomputer110 and I/O interface circuit118 control right and left stride length as a function of user input supplied viauser input devices112 or in an automatic stride length adjustment mode in whichcomputer110 and I/O interface circuit118 automatically control right and left stride length based on sensor output.
• As shown inFIG. 8, theuser input devices112 oncontrol panel24 may include, for example, separatelighted pushbuttons130 and131 enabling the user to select between manual and auto stride length adjustment modes, withpushbutton130 or131 being illuminated to indicate the current mode of operation. When in the manual stride length adjustment mode,computer110 signals I/O interface circuit to increase or decrease stride length in response to user input viaseparate pushbuttons132 and133 and a stridelength sensitivity knob134 allows the user control the amount by whichcomputer110signals actuators34,35,62 and/or63 to increase or decrease stride length each time the user pressesbutton132 or133.
• In the automatic stride length adjustment mode,computer112 adjusts left and right stride length in response to a combination of information contained in the H_FORCE_R and H_FORCE_L output signals of the right and left horizontal strain gauges58-61 and the POSITION output signal ofangular position sensor126 ofFIG. 7 indicating the angular position ofcrank rod64 ofFIG. 1. As discussed above,left drawbar link36 oflinkage mechanism22 is rotatably connected to crankmember12 viacrank rod64, and as crankrod64 rotates about theaxis66 ofcrank member12,linkage mechanism22 causes rightleft member36 and leftfootpad50 to oscillate back and forth through a horizontal distance controlled byactuators34 and62.
• FIG. 9 depicts the circular path ofcrank rod64 about theaxis66 ofcrank member12. When crankrod64 is at its maximum forward position, leftfootpad50 has reached its maximum forward position,right footpad51 has reached its maximum rearward position, and the POSITION signal output ofposition sensor126 indicates that crankrod64 is at 0 degrees. Conversely, when crankrod64 reaches its maximum rearward position, leftfootpad50 reaches its maximum rearward position,right footpad51 reaches its maximum forward position, and the POSITION signal output ofposition sensor126 indicates crankrod64 is at 180 degrees.
• A user rotates crankmember12 by shifting most of his or her weight toleft side footpad50 while crankrod64 is moving counterclockwise from 90 to 270 degrees, and by shifting most of his or her weight toright side footpad51 when crankrod64 is moving counterclockwise from 270 to 90 degrees. The percentage of the user's weight allocated to the right and left during each half cycle of crank rotation controls the downward vertical forces the user applies to footpads50 and51 and affects the rotational velocity ofcrank member12. Vertical stain gauges60 and61 sense the vertical forces on the footpads. The user's leg muscles can also apply forward and rearward directed horizontal forces to footpads50 and51 that are sensed by left and right horizontal strain gauges58-61. The horizontal forces onfootpads50 and51 also affect rotational velocity, but normally to a lesser extent than the vertical forces.
• In the automatic stride length adjustment mode,computer110 automatically increases or decreases stride length by increasing or decreasing the lengths ofactuators34,35,62 and63 in response to the H_FORCE_L and H_FORCE_R signals produced byhorizontal strain gauges58 and59 and the POSITION signal produced byposition sensor126. We define the following horizontal forces as being positive in the forward direction from the user's point of view:
• F_HL: horizontal force onleft footpad50,
• F_HR: horizontal force onright footpad51,
• F_HHT: a high horizontal threshold level force, and
• F_LHT: a low horizontal threshold level force,
• Computer110 stores parameters indicating the high and low horizontal threshold forces F_HHTand F_LHTas user adjustable constants in its memory. In the automatic stride length adjustment mode,computer110signals interface circuit118 to carry out the following operations:
• Increment left side stride length when F_HL>F_HHTand crankrod64 resides between 80 and 100 degrees,
• Increment right side stride length when F_HR>F_HHTand crankrod64 resides between 260 and 280 degrees,
• Decrement left side stride length when F_HL<F_LHTand crankrod64 resides between 80 and 100 degrees, and
• Decrement right side stride length when F_HR<F_LHTand crankrod64 resides between 260 and 280 degrees.
• Whencomputer110 follows the above rule, a user quickly learns that sufficiently increasing or decreasing the horizontal forces of a footpad when the footpad is at the top of its forward stride will cause an increase or decrease in stride length. Although the position ranges forcrank rod64 suggested above are provided for illustrative purposes, those of skill in the art will appreciate that in other embodiments of the invention, the computer may employ position ranges that vary from those indicated above when testing for the user's desire to increase or decrease stride length.
• FIG. 10 is a flow chart for a program executed bycomputer110 when in the automatic stride length adjustment mode.Computer110 initially iteratively samples the right horizontal force data F_HRand the POSITION data provided by interface circuit18 (step202) until it determines from the POSITION data that crankrod64 resides between 260-280 degrees (step204). If the last sampled value of right horizontal force data F_HRexceeds the high horizontal threshold level force F_HHT(step206),computer110signals interface circuit118 to increment the right stride length (step208). If the last sampled value of right horizontal force data F_HRis less than the low horizontal threshold level force F_LhT(step210),computer110signals interface circuit118 to decrement the right stride length (step212). Afterstep208 or212, or afterstep210 if the last sampled value of right horizontal force data F_HRis between the low horizontal threshold level force F_LHTand the high horizontal level threshold force F_HHT,computer110 begins iteratively sampling the left horizontal force data F_HLand the POSITION data supplied by interface critic118 (step214) until it determines from the POSITION data that crankrod64 resides between 80 and 100 degrees (step216). If the last sampled value of left horizontal force data F_HLexceeds the high threshold level force F_HHT(step218),computer110signals interface circuit118 to increment the left stride length (step220). If the last sampled value of left horizontal force data F_HLis less than the low threshold level force F_LHT(step222),computer110signals interface circuit118 to decrement the left stride length (step224). Afterstep220 or224, or afterstep222 if the last sampled value of left horizontal force data F_HLis between the low horizontal threshold level force F_LHTand the high horizontal level threshold force F_HHT,computer110 returns to step202. Note thatcomputer110 increments or decrements right or left stride length at most only once during each rotational cycle. The amount by whichcomputer110 increases left or right stride length atstep208 or220 increases with the amount by which the last sampled horizontal force F_HRor F_HLexceeds the high threshold level F_HL. Similarly, the amount by whichcomputer110 decreases left or right stride length atstep212 or224 increases with the amount by which the low threshold level F_HLexceeds the last sampled horizontal force F_HRor F_HL.
• Thus in the automatic stride length adjustment mode, the user can maintain a constant stride right and left stride lengths by keeping the horizontal forces on the left andright footpads50 and51 between the high and low horizontal threshold levels F_HHTand F_LHTwhile the left or right footpad is near its high point and moving forward, and can increase or decrease left or right stride length by increasing or decreasing the horizontal force on right or leftfootpad50 or17 above or below the high or low threshold levels while the footpad is near its high point and moving forward. The particular ranges of positions employed at decision steps204 and216 are a matter of design choice and can vary from those shown inFIG. 10. For example atstep204computer110 could determine whether crankrod64 is within a range of 90-120 degrees and atstep216computer110 could determine whether crankrod64 is in a range of 270-300 degrees. In the automatic stride length adjustment mode, the user can adjust the values of the two threshold level force constants F_LHTand F_HHTup or down using stridelength sensitivity knob134.Computer110 displays the current stride height and length and the current threshold levels F_LHTand F_HHTondisplay monitor114. In the preferred embodiment of the invention, right and left stride paths, including their lengths and heights, are independently adjustable, which is advantageous because users having non-symmetric leg strengths sometimes prefer slightly differing right and left strides. In other embodiments of the invention,computer110 automatically adjusts right and left stride height and/or length concurrently so they are always similar. This could be implemented, for example, by changing the algorithm ofFIG. 10 so that atsteps208 and220 both right and left stride lengths are incremented and so that atsteps212 and224 both right and left stride lengths are decremented.
• In the preferred embodiment of the invention, pushbuttons and knobs132-134 allow the user to control right and left stride lengths concurrently when the computer is operating in the manual stride adjustment mode so that they are always similar.
• However additional pushbuttons can be provided oncontrol panel24 to allow the user to independently increment and decrement right and length stride length whencomputer110 is operating in the manual stride length adjustment mode.
Stride Height Adjustment
• The user can also commandcomputer110 to operate in either a manual stride height adjustment mode wherein the user directly controls stride height viauser input devices112 or in an automatic height length adjustment mode in which the computer automatically controls stride height based on sensor input.
• As shown inFIG. 8, theuser input devices112 oncontrol panel24 may include, for example, separatelighted pushbuttons135 and136 enabling the user to select between manual and auto stride height adjustment modes, withpushbutton135 or136 being illuminated to indicate the current mode of operation. When in the manual stride height adjustment mode,computer110 signals I/O interface circuit to increase or decrease stride height in response to user input viaseparate pushbuttons137 and138 and a strideheight sensitivity knob140 allows the user control the amount by whichcomputer110 increases or decreases stride length each time the user pressesbutton137 or138. While the preferred embodiment of the invention provides switches and knobs130-140 for the above-described user input functions, one of skill in the art will appreciate thatinput devices112 provided for these function are a matter of design choice and can be implemented by any of a variety of devices including, for example, keyboards, keypads, touch screens, and the like.
• In the automatic stride height adjustment mode,computer112 adjusts left and right stride height in response to a combination of information contained in the V_FORCE_R and V_FORCE_L output signals of the right and left horizontal strain gauges100 and101 and the POSITION output signal ofangular position sensor126 ofFIG. 7. We define the following vertical forces on the footpads as being positive in the upward direction and negative in the downward direction from the user's point of view:
• F_VR: vertical force onright footpad51,
• F_VL: vertical force onleft footpad50,
• F_HVT: a high vertical threshold level force, and
• F_LVT: a low vertical threshold level force.
• Interface circuit118 converts the V_FORCE_R and V_FORCE_L output signals of the right and left horizontal strain gauges100 and101 into data representing the vertical forces F_VRand F_VLthe user applies the left andright footpads50 and51 and permitscomputer110 to read access that data.Computer110 stores the high and low vertical threshold forces F_HVTand F_LVTas user adjustable constants in its memory.
• Assuming upward directed vertical forces are positive, the vertical forces F_VRand F_VLthe user applies to the left andright footpads50 and51 are negative (downward directed) and vary as the user rotates crankmember12 by shifting his or her weight from one footpad to the other during each rotation cycle. When crankrod64 resides between 90 and 100 degrees, most of the user's weight will be onright footpad51 but the user will normally continue to apply a modest downward force onleft footpad50. However it is possible for the user to shift all or almost all of his or her weight toright footpad51 when crankrod64 is between 90 and 100 degrees thereby causing vertical force F_VLonleft footpad50 greater (less negative) than a small negative threshold force F_HVT. In the automatic stride height adjustment mode,computer118 increases left side stride height when F_VLis greater (less negative) than F_HVTwhencrank rod64 is between 90 and 100 degrees. Thus the user can signalcomputer110 to increase left side stride height by removing most of all of his or her weight fromfootpad50 when crankrod64 is between 90 and 100 degrees. Similarly,computer118 increases right side stride height when F_VLis greater (less negative) than F_HVTwhencrank rod64 is between 270 and 280 degrees. Thus the user can signalcomputer110 to increase left side stride height by removing most of all of his or her weight fromfootpad51 when crankrod64 is between 270 and 280 degrees.
• In the automatic stride height adjustment mode,computer118 decreases left side stride height when F_VRis less than (more negative) than a low vertical threshold level F_LVTwhencrank rod64 is between 90 and 100 degrees. Thus the user can signalcomputer110 to decrease left side stride height by shifting a sufficient amount of all of his or her weight to leftfootpad50 when crankrod64 is between 90 and 100 degrees. Similarly,computer118 decreases right side stride height when F_VK\Lis less (more negative) than F_VTwhencrank rod64 is between 270 and 280 degrees. Thus the user can signalcomputer110 to decrease right side stride height by a sufficient amount of his or her weight toright footpad51 when crankrod64 resides between 270 and 280 degrees. In the automatic stride height adjustment mode, the user can adjust the magnitude of low vertical threshold level F_LVTusing stride heightsensitive control knob140 andcomputer110signals interface circuit118 to carry out the following operations:
• Increment left side stride height when F_VL>F_HVTand crankrod64 resides between 90 and 100 degrees,
• Increment right side stride height when F_VR>F_HVTand crankrod64 resides between 270 and 280 degrees,
• Decrement left side stride height when F_VL<F_LVTand crankrod64 resides between 90-100 degrees, and
• Decrement right side stride height when F_VR<F_LVTand crankrod64 resides between 270 and 280 degrees.
• The position ranges forcrank rod64 discussed above are provided for illustrative purposes. Those of skill in the art will appreciate that in other embodiments of the invention, the computer may employ position ranges that vary from those indicated above when testing for the user's desire to increase or decrease stride height and the user will learn to apply the appropriate vertical forces to the footpad at the appropriate points along their paths as needed to initiate desired changes in stride height.
• FIG. 11 is a flow chart for a program executed bycomputer110 when in the automatic stride height adjustment mode.Computer110 initially iteratively samples the right and left vertical force data F_VRand F_VLand the POSITION data provided by interface circuit18 (step302) until it determines from the POSITION data that crankrod64 resides between 270 and 280 degrees (step304). If the last sampled value of right vertical force data F_VRexceeds the positive high threshold level force F_HVT(step306),computer110signals interface circuit118 to increment the right stride height (step308). If the last sampled value of left vertical force data F_VLexceeds low threshold level force F_LVT(step310),computer110signals interface circuit118 to decrement the left stride height (step312). Afterstep308 or312, or afterstep310 if results of bothsteps306 and310 are “NO”,computer110 resumes iteratively sampling the right and left vertical force data F_VRand F_VLand the POSITION data (step314) until it determines from the POSITION data that crankrod64 resides between 260 and 280 degrees (step316). If the last sampled value of left vertical force data F_VLexceeds the high threshold level force F_HVT(step318),computer110signals interface circuit118 to increment the left stride height (step320). If the last sampled value of left vertical force data F_HLexceeds the low threshold level force F_LVT(step322),computer110signals interface circuit118 to decrement the left stride height (step324). Afterstep320 or324 or afterstep322 if the result of bothsteps318 and322 is “NO”,computer110 returns to step302. Note thatcomputer110 increments or decrements right or left stride height at most only once during each rotational cycle. The amount by whichcomputer110 increases or decreases left or right stride height atstep308,312,320 or324 increases with the amount by which the last sampled vertical force F_HRor F_HLexceeds the high or low threshold level F_VHTor F_VHT.
• Thus in the automatic stride height adjustment mode, the user can maintain a constant right and left stride height by keeping the vertical forces on the right and leftfootpads50 and51 between the high or low threshold levels F_VHTor F_VHTwhile the footpads are approaching their high points. The user can increase right or left stride height by lifting his right or left foot off the right or leftfootpad50 or17 as it nears its high point and can decrease right or left stride height by pushing down sufficiently hard on the right or leftfootpad50 or17 as it nears its high point.
• In the preferred embodiment of the invention, right and left stride height are independently adjustable in the automatic mode, which is advantageous because users having non-symmetric legs sometimes prefer slightly differing right and left stride heights. In other embodiments of the invention,computer110 can automatically adjust right and left stride height concurrently so they are always similar. This could be implemented, for example, by changing the algorithm ofFIG. 10 so that atsteps308 and320 both right and left stride heights are incremented and so that atsteps312 and324 both right and left stride heights are decremented.
• In the preferred embodiment of the invention, pushbuttons and knobs137-140 allow the user to control right and left stride height concurrently when the computer is operating in the manual stride adjustment mode so that they are always similar. However additional pushbuttons can be provided oncontrol panel24 to allow the user to signalcomputer110 to independently increment and decrement right and stride height whencomputer110 is operating in the manual stride height adjustment mode.
• Those of skill in the art will also appreciate that the particular ranges of positions employed at decision steps304 and316 are a matter of design choice and can vary from that shown inFIG. 10. For example atstep304computer110 could determine whether crankrod64 is within a range of 90-120 degrees and atstep316computer110 could determine whether crankrod64 is in a range of 270-300 degrees.
• Stride Length Control Based on Angular Velocity and Position
• In the automatic stride length control mode,computer110 determines when to increase or decrease stride length base as a function of the POSITION signal output ofangular position sensor126 and of the H_FORCE_R and H_FORCE_L output signals ofhorizontal strain gauges59 and60. In an alternative embodiment of the invention,computer110 determines when to change stride length as a function of the POSITION signal and the VELOCITY signal output ofregenerative brake46, thereby eliminating the need forhorizontal strain gauges59 and60. This is particularly advantageous in an exercise apparatus that does not provide automatic stride height control mode and therefore does not require vertical strain gauges60 and61. Eliminating the need for all strain gauges98-101 reduces the complexity offootpads50 and51 and allows them to be formed as integral parts offoot members16 and17 and the wiring needed to deliver the strain gauge output signals to controlpanel24 can be eliminated.
• FIG. 12 plots the magnitude V of the VELOCITY signal as a function of both time and crank position as the user movesfootpads50 and51 through a full rotation cycle ofcrank member12 as indicated by the POSITION signal output ofangular position sensor128.FIG. 13 plots the acceleration A ofcrank member12 as a function the angular position ofcrank rod64.FIG. 12 also graphically depicts atangular positions 0, 270, 180 and 90 degree positions ofcrank rod64 ofFIG. 1 as it rotates about crankaxis66 as indicated by the POSITION signal and shows the direction of the horizontal and vertical forces on crank. crank resulting from user forces applied to the footpads.
• At 0 degrees, the user applies the majority of his or her weight onfootpad50 to apply a net downward force F_VLoncrank rod64 which accelerates crank rotation by overcoming resistive forces applied byregenerative brake46. Since at 0 degrees, crankrod64 is at its maximum horizontal distance from crankaxis66 ofcranks20 the net vertical force F_VLoncrank rod64 maximally accelerates crankmember12 as indicated by the rapidly increasing magnitude V of the VELOCITY signal at the 0 degree position. As crankrod64 approaches 270 degrees, crank acceleration declines due to the decreasing leverage afforded by the declining horizontal distance between crankrod64 and crankaxis66 and because the user has begin shifting his or her weight betweenfootpads50 and51 so that the forces on left crankrode64 and its right crankrod counter part65 tend to cancel one another with respect to accelerating crankmember12. Angular velocity peaks at about 315 degrees when the rotational forces provided by the user fall below the resistive forces provided byregenerative brake14. As crankrod64 reaches its 270 degree position, the vertical forces on crankrods64 and65 have no effect on acceleration and crank deceleration is at a maximum, as indicated by the large negative slope of VELOCITY signal magnitude V. Velocity continues to decline to a minimum when crankrod64 reaches its 225 degree position. Maximum rotational acceleration is again achieved when crankrod64reaches 180 degrees due to the large net vertical force onpin45 at a maximum horizontal distance from crankaxis66.
• FIG. 12 plots angular velocity V and acceleration ofcrank rod64 ofFIG. 1 as a function of the angular position ofcrank rod64 during one cycle of pin rotation and also graphically depicts the net vertical forces F_VRand F_VLthe user applies topins64 and654 and the horizontal forces F_HRand F_HLthe user applies to points44 and45.FIG. 12 is drawn with the assumption that the user is maintaining a steady pace and that F_HLand F_HRare zero because the user is applying no horizontal forces to footpads50 and51.
• Even when the user pedals at a constant rate to provide a constant average angular velocity, the instantaneous angular velocity V will vary as shown inFIG. 12 during each cycle of rotation. At the 0 and 180-degree positions, acceleration A is at its positive maximum positive because F_V, being maximally horizontally displaced fromcrank member axis66, rapidly accelerates the crank. At the 90 and 270 degree positions, acceleration is at its negative minimum because F_V, having no horizontal displacement fromcrank member axis66, has no effect on crank acceleration and the crank rapidly decelerates due to the resistive force on crankmember12 provided bybrake46. The “net vertical force” F_Vis defined as the difference between the vertical forces F_VRand F_VLvia crankrods64 and65 and is directed at the point receiving the larger of the two forces
• The user could increase his or her pace by increasing the net force F_Vapplied to applied to crankrods64 and64, and in such case, both the velocity and acceleration curves ofFIG. 12 would trend upward until the resistance provided byregenerative brake46, which increases with rotational velocity, balances the increased cranking force provided by the user. At that point the velocity curve would look similar to that ofFIG. 12, but would be shifted upward.
• Acceleration A at any given position P of crankrod64 is a function of the net vertical force F_Von the crankrods64 and65 applied vialifter links70 and71 ofFIG. 1, the net horizontal forces F_Hon crankrods64 and65 and the resistive force F_Rprovided byregenerative brake46, and the angular position P of crankrod64.
• 
  A=f(F_V,F_HR,F_HL,F_R,P)
• The resistive force F_Rprovided byregenerative brake46 is a function of the rotational velocity V of thecrank member12 and the magnitude of the resistance R ofresistor128 ofFIG. 7. Thus
• 
  A=g(F_V,F_HR,F_HL,V,R,P)
• When the user applies no horizontal forces F_HL, F_HRto footpads50 and51, then the negative crank acceleration at the 270 degree position ofcrank rod64 arises only from resistive force F_Rdue to V and R because the net vertical force F_Vis zero when P=270 degrees. Thus the expected acceleration A at the 270 degree position when net horizontal forces are 0,
• 
  A=g(0,0,0,V,R,270)
• We define a variable A_E270as an “expected” crank acceleration for a given velocity at the 270 degree pin position when horizontal forces F_HL, F_HRon crankrods64 and65 are zero. The expected 270 degree position crank acceleration A_E270is a function only of V and R.
• 
  A_E270=h(V,R)
• The expected acceleration A_E90at the 90-degree position ofcrank rod64 is a similar function of V and R when horizontal forces on crankrods64 and65 are zero.
• 
  A_E90=h(V,R)
• During each crank cycle,computer110 samples the POSITION and VELOCITY signals to determine the magnitude V of crank velocity whenever the POSITION signal indicates crankrod64 is at either the 90 or 270 degree position. Knowing the value to which it most recently set resistance R,computer110 then computes A_E90and A_E270based on a stored equation or lookup table model of the above function h(V,R). The function is experimentally determined at the factory at the time the exercise apparatus is built and then stored in non-volatile memory ofcomputer110.
Stride Height and Length Control for Backward Mode Operation.
• Referring toFIG. 1, when the user operatesexercise apparatus10 in a “forward mode” as described above such that crankrod64 rotates counter-clockwise about the axis ofcrank member12 as viewed from the left side of the apparatus, the user's feet will move in much the same way as the would if the user were walking forward on a flat surface. However the user can alternatively operateexercise apparatus10 in a “backward mode” by rotatingcrank rod64 in a clock-wise direction, thereby moving his or her feet in a manner similar to walking backwards.Computer110 determines whether the user is operating the apparatus in the forward or backward mode based on how the POSITION signal output ofangular position sensor126 changes with time. During backward mode operation, when the user has selected automatic stride height and/or length control,computer110 automatically adjusts stride height and/or length based on user applied forces using algorithms substantially similar to the forward walking mode algorithms described above, except that the angular positions at which user forces are sensed differ in the reverse mode. In thebackward mode computer110 will carry out the following actions:
• Increment left side stride height when F_VL>F_HVTand crankrod64 resides between 80 and 90 degrees,
• Increment right side stride height when F_VR>F_HVTand crankrod64 resides between 280 and 10 degrees,
• Decrement left side stride height when F_VL<F_LVTand crankrod64 resides between 80 and 90 degrees, and
• Decrement right side stride height when F_VR<F_LVTand crankrod64 resides between 280 and 10 degrees.
Interface Circuit
• Interface circuit118 andcomputer110 determine the “actual crank accelerations” A_A90and A_E270atcrank rod64positions 90 and 270 by differentiating the VELOCITY signal and sampling the result whenever the POSITION signal indicates crankrod64 is at either the 90 or 270 degree position.FIG. 13 depicts a circuit withininterface circuit118 for providingcomputer110 with data V90, V270 representing rotational velocity at the 90 and 270 degree positions, data AA90 and AA270 representing actual acceleration at the 90 and 270 degree positions, and a data sequence V representing instantaneous rotational velocity. Adigitizer340 digitizes the VELOCITY signal many times during each rotational cycle in response to a CLOCK signal to produce the V data sequence. A differentiatingamplifier350 differentiates the VELOCITY signal and adigitizer352 also clocked by the CLOCK signal, digitizes the result to produce another data sequence representing the angular crank accelerationA. Position detector356 checks the POSITION signal on each pulse of the CLOCK, supplying an interrupt signal INT₉₀tocomputer110 whenever crankrod64 is at the 90 degree position and supplying an interrupt signal INT₂₇₀tocomputer110 whenever crankrod64 is at the 270 degree position. An OR gate380 Ors the INT₉₀and INT₂₇₀signals to produce a signal for clocking a pair ofregisters342 and354 for storing the V and A outputs ofdigitizers340 and352, respectively. Interrupt signals INT₉₀and INT₂₇₀tellcomputer110 to read the contents ofregisters342 and354. When INT₉₀is asserted,computer110 assumes the contents ofregisters342 and354 are V₉₀and A_A90, and when INT₂₇₀is asserted,computer110 assumes the contents ofregisters342 and354 are V₂₇₀and A₂₇₀. Since those of skill in the art will appreciate that there are many other possible ways to carry out the function of the circuit ofFIG. 13 and that the approach used is a matter of design choice.
• The difference between the expected and actual accelerations at the 90 and 270-degree positions ofcrank rod64 is a function of the amount and direction of net horizontal force F_Hthe user is applying to pins.
• 
  F_H90=m(A_A90−A_E90)
• 
  F_H270=m(A_A270−A_E270)
• The constant m is the mass of the system the horizontal forces F_HRand F_HLmust move when accelerating the crank at the 90 and 270-degree positions.
• In the alternative embodiment of the invention,computer110 determines (A_A90−A_E90) and (A_A270−A_E270) each time crankrod64 arrives at it 90 or 270 degree position, and determines whether to increase or decrease stride length depending on the magnitude of the difference. When (A_A90−A_E90) or (A_A270−A_E270) is larger than a high threshold value,computer110 increases both right and left side stride length. When (A_A90−A_E90) or (A_A270−A_E270) is less than a low threshold value,computer110 decreases both right and left side stride length.
• Referring toFIGS. 1 and 2, note that the user can also apply horizontal forces to crankrods64 and65 throughlinkages22 and23 by pushing and pulling onhandle bars40 and41. Since in the alternative embodiment of the invention stride length is adjusted in response to horizontal forces on crankrod64 regardless of whether they originate from user forces applied topads16 or17 to hand grips40 and41, the user can increase or decrease stride length by increasing or decreasing forces he or she applies to handgrips40 and41 when crankrod64 is at the 90 or 270 degree position.
Resistance Control
• Referring toFIGS. 1,7 and8,control panel24 includes a pair ofpushbuttons142 and142 enabling the user to commandcomputer110 to increase or decrease the resistance to rotation ofcranks121 and122 provided byregenerative brake46 by signaling I/O interface circuit118 to increase or decrease the resistance ofresistor128.Display devices114 ofFIG. 7 include anumeric display panel143 for indicating the current resistance level.
Programmed Exercise
• Computer110 can operate in a “Program Mode” in which it automatically varies the resistance ofbrake46, stride length, and/or stride height at various times during exercise. Referring toFIG. 8, the user presses either of a pair ofpushbuttons142 oncontrol panel24 to tellcomputer110 whether it is to turn the program mode on or off.
• Referring toFIGS. 7 and 8,display devices114 anduser input devices112 withincontrol panel24 include in addition to control buttons andknobs142 include adisplay monitor141 for presenting data and other displays under control ofcomputer110.Display monitor141 includes a conventional touchscreen for signalingcomputer110 whenever the user has touched the surface of the display monitor and for indicating the area of the monitor the user has touched.Computer110 displays push button icons and menu items the user can touch to provide input commands tocomputer110. In the program mode,computer110 generates a video of terrain onmonitor141 to simulate what the user might see if the user were running in such a terrain and also changes resistance, stride length, and/or stride height to simulate the effects of changes in the slope of the terrain viewed ondisplay monitor141. For example, resistance and stride height are increased and stride length is decreased when the display shows the user is traveling uphill while resistance and stride height are decreased and stride length is increased when the display shows the user is traveling downhill.Network adapter116 suitably allowscomputer110 to download various programs via the Internet in response to commands from the user via thetouchscreen monitor141. The user selects from among stored exercise programs listed as menu items on display monitor by using the touchscreen to select the appropriate menu item.
• Computer110 can use the touchscreen ofmonitor141 to receive user input allowing the user, for example, to
• • (a) Log in as a user or log out
  • (b) Select exercise parameters being displayed.
  • (c) Select an exercise program,
  • (d) Download a new exercise program.
• Computer110 also uses display monitor141 to display a variety of data regarding user exercise in graphical or numeric form including, but not limited to:
• • (a) Current resistance level,
  • (b) Elapsed exercise time,
  • (c) Current speed of exercise,
  • (d) Average speed of exercise,
  • (e) Number of calories burned during exercise
  • (f) Simulated distance traveled during exercise
  • (g) Simulated elevation gains and losses during exercise,
  • (h) User's weight,
  • (j) Available exercise programs,
  • (k) Currently selected exercise program,
  • (l) Current stride height and length
  • (m) Historical exercise data for each user.
• Those of skill in the art will appreciate thatcomputer110 can be programmed to determine and display exercise speed, calories burned, distance traveled, and user weight from information provided by I/O interface118 in response to signals it receives representing forces on the footpads, rotational velocity and position. Stride height, stride length and resistance are directly controlled bycomputer110 and therefore known the computer. Historical exercise data for each user which may be displayed in tabular or graphical form, can include, for example, daily number of calories burned, distances traveled, exercise programs completed and times required to complete them.
• The present invention has been described with the understanding that persons skilled in the art will recognize additional embodiments, improvements, and/or applications that nonetheless fall within the scope of the invention. For example, while the invention has been illustrated in connection with an elliptical exercise machine having a particular type of linkage for coupling each footpad to the frame and for controlling the path that the footpad follows, the invention in its broadest sense can be practiced in connection with exercise with any kind of linkage that can respond to input signals by adjusting one or more dimensions of that path. Therefore, the scope of the present invention as defined in any one the claims appended hereto is not intended to be limited to the particular linkage described in the specification and drawings except to the extent the claim recites details of such linkage. Also while the drawings and specification have described alternative methods and apparatuses for monitoring user forces on the footpad, including the use of strain gauges on the foot pad and processing the angular velocity signal to determine crank member acceleration, those of skill in the art will appreciate that the invention can be practiced using other methods and apparatuses for monitoring those forces. Therefore, the scope of the present invention as defined in any one of the claims appended hereto is not intended to be limited to any particular method of monitoring such forces described in the specification and drawings except to the extent that the claim may recite details of such method or apparatus. Those of skill in the art will also appreciate that any of a variety of methods and apparatuses for sensing the angular position of a rotatable member are known in the art and could be employed for that purpose when practicing the invention. Therefore, the scope of the present invention as recited in any one of the claims appended hereto is not intended to be limited to any particular method for sensing forces described in the specification and drawings except to the extent the claim may recite specific details of such method or apparatus. While the invention has been illustrated as being used in an elliptical exercise machine that guides a user's feet in an elliptical type of closed path, the principles of the invention can be used to automatically control path dimensions in other exercise machines such as, for example, steppers, gliders, skiers and climbers, that guide a user's feet in other types of closed paths including, for example, linear and/or arcuate paths that can be adjusted in one or more dimension.

Claims (34)

1. An exercise apparatus comprising:

a frame;

a footpad for supporting a user's foot;

a linkage for coupling the footpad to the frame and for guiding the footpad in a closed path in response to a force applied to the footpad by the user's foot, the linkage including a rotatable member having an angular position indicative of a position of the footpad within the closed path, wherein the linkage adjusts a dimension of the closed path in response to an electrical control signal supplied as input to the linkage; and

a control system for monitoring the angular position of the rotatable member, for monitoring the force applied to the footpad, and for generating the control signal such that the linkage adjusts the dimension as a function of the monitored force on the footpad and of the angular position of the rotatable member.

2. The exercise apparatus in accordance withclaim 1 wherein the control system generates the control signal to cause the linkage to increase and decrease the path dimension when it senses particular combinations the force and the angular position, thereby permitting the user to control the path dimension by controlling the force applied to the footpad.

3. The exercise apparatus in accordance withclaim 2

wherein the control system controls the control signal such that the linkage alters the dimension when a magnitude of the force is outside a magnitude range while the angular position of the rotatable member is within a position range,

such that the linkage refrains from adjusting the dimension when the magnitude of the force is outside the magnitude range, and

such that the linkage refrains from adjusting the dimension when the angular position of the rotatable member is outside the position range.

4. The exercise apparatus in accordance withclaim 1 further comprising:

a strain gauge coupled between the footpad and the linkage for generating a force indicating signal indicative of the magnitude of the force,

wherein the control system monitors the force by monitoring the force indicating signal.

5. The exercise apparatus in accordance withclaim 1 wherein the force and the dimension are in substantially parallel directions.

6. The exercise apparatus in accordance withclaim 1 wherein the control system monitors the force by monitoring a rotational velocity of the rotatable member, and based on the monitored rotational velocity, determining a rotational acceleration of the rotatable member that is indicative of the magnitude of the force when the angular position of the rotatable member is within the position range.

7. The exercise apparatus in accordance withclaim 1 wherein the dimension of the closed path defines a stride length of the user's foot.

8. The exercise apparatus in accordance withclaim 1 wherein the dimension of the closed path defines a stride height of the user's foot.

9. An exercise apparatus comprising

a frame;

a footpad for supporting a user's foot;

a linkage for coupling the footpad to the frame and for guiding the footpad in a closed path in response to first and second forces applied in first and second directions, respectively, to the footpad by the user's foot, wherein the linkage includes a rotatable member having an angular position that changes with a position of the footpad within the closed path, and wherein the linkage adjusts first and second dimensions of the closed path in response to electrical control signals supplied as inputs to the linkage; and

a control system for monitoring the angular position of the rotatable member, for monitoring magnitudes of first and second forces, and for generating the control signals such that the linkage adjusts the first and second dimensions as functions of the monitored first and second forces and of the monitored angular position of the rotatable member.

10. The exercise apparatus in accordance withclaim 9 wherein the control signals cause the linkage to increase and decrease the path dimensions when it senses particular combinations of the angular position and first and second forces, thereby permitting the user to control the path dimensions by controlling the force applied to the footpad.

11. The exercise apparatus in accordance withclaim 10

wherein the control system controls the first and second control signals such that the linkage alters the first dimension when a magnitude of the first force is outside a first magnitude range while the angular position of the rotatable member is within a first position range, such that the linkage refrains from adjusting the first dimension when the magnitude of the first force is outside the first magnitude range, and such that the linkage refrains from adjusting the first dimension when the angular position of the rotatable member is outside the first position range, and

such that the linkage alters the second dimension when a magnitude of the second force is outside a second magnitude range while the angular position of the rotatable member is within a second position range, such that the linkage refrains from adjusting the second dimension when the magnitude of the second force is outside the second magnitude range, and such that the linkage refrains from adjusting the second dimension when the angular position of the rotatable member is outside the second position range.

12. The exercise apparatus in accordance withclaim 9 further comprising:

a first strain gauge coupled between the footpad and the linkage for generating a first force indicating signal indicative of the magnitude of the first force, and

a second strain gauge coupled between the footpad and the linkage for generating a second force indicating signal indicative of the magnitude of the second force,

wherein the control system monitors the first and second forces by monitoring the first and second force indicating signals.

13. The exercise apparatus in accordance withclaim 9 wherein the first dimension of the closed path defines a stride length of the user's foot, and

wherein the second dimension of the closed path defines a stride height of the user's foot.

14. A method for controlling an exercise apparatus having a frame, a footpad for supporting a user's foot, and a linkage for coupling the footpad to the frame and for guiding the footpad in a closed path in response to a force applied to the footpad by the user's foot, wherein the linkage includes a rotatable member having an angular position that changes with a position of the footpad within the closed path, and wherein the linkage adjusts a dimension of the closed path in response to an electrical control signal supplied as input to the linkage, the method comprising the steps of

a. monitoring the angular position of the rotatable member,

b. monitoring a magnitude of the force, and

c. controlling the control signal such that the linkage adjusts the dimension as a function of the monitored force on the footpad and of the monitored angular position of the rotatable member.

15. The method in accordance withclaim 14 wherein the control signals cause the linkage to increase and decrease the path dimension when it senses particular combinations of the monitored angular position and the monitored force, thereby permitting the user to control the path dimension by controlling the force applied to the footpad.

16. The method in accordance withclaim 14

wherein the exercise apparatus includes a strain gauge coupled between the footpad and the linkage for generating a force indicating signal indicative of the magnitude of the force, and

wherein step b comprises monitoring the force indicating signal.

17. The method in accordance withclaim 14

wherein step c comprises controlling the control signal

such that the linkage alters the dimension when a magnitude of the force is outside a magnitude range while the angular position of the rotatable member is within a position range,

such that the linkage refrains from adjusting the dimension when the magnitude of the force is outside the magnitude range, and

such that the linkage refrains from adjusting the dimension when the angular position of the rotatable member is outside the position range.

18. The method in accordance withclaim 17 wherein the force and the dimension are in substantially parallel directions.

19. The method in accordance withclaim 14 wherein step b comprises the substeps of:

b1. monitoring a rotational velocity of the rotatable member, and

b2. based on the monitored rotational velocity, determining a rotational acceleration of the rotatable member indicative of the magnitude of the force when the angular position of the rotatable member is within the position range.

20. The exercise apparatus in accordance withclaim 14 wherein the dimension of the closed path defines a stride length of the user's foot.

21. The method in accordance withclaim 14 wherein the dimension of the closed path defines a stride height of the user's foot.

22. A method for controlling an exercise apparatus having a frame, a footpad for supporting a user's foot, and a linkage for coupling the footpad to the frame and for guiding the footpad in a closed path in response to first and second forces applied in differing directions to the footpad by the user's foot, wherein the linkage includes a rotatable member having an angular position that changes with a position of the footpad within the closed path, and wherein the linkage adjusts first and second dimensions of the closed path in response to a plurality of electrical control signals supplied as inputs to the linkage, the method comprising the steps of

a. monitoring the angular position of the rotatable member,

b. monitoring magnitudes of first and second forces, and

c. controlling the control signals such that the linkage adjusts the first and second dimensions as functions of the monitored first and second forces and the monitored angular position of the rotatable member.

23. The method in accordance withclaim 22 wherein the control signals cause the linkage to increase and decrease the path dimensions when it senses particular combinations of the monitored angular position and first and second forces, thereby permitting the user to control the path dimensions by controlling the force applied to the footpad.

24. The method in accordance withclaim 22

wherein the exercise apparatus includes a first strain gauge coupled between the footpad and the linkage for generating a first force indicating signal indicative of the magnitude of the first force,

wherein the exercise apparatus includes a second strain gauge coupled between the footpad and the linkage for generating a second force indicating signal indicative of the magnitude of the second force, and

wherein step b comprises monitoring the first and second force indicating signals.

25. The method in accordance withclaim 22

wherein step c comprises controlling the first and second control signal

such that the linkage alters the first dimension when a magnitude of the first force is outside a first magnitude range while the angular position of the rotatable member is within a first position range, such that the linkage refrains from adjusting the first dimension when the magnitude of the first force is outside the first magnitude range, and such that the linkage refrains from adjusting the first dimension when the angular position of the rotatable member is outside the first position range, and

such that the linkage alters the second dimension when a magnitude of the second force is outside a second magnitude range while the angular position of the rotatable member is within a second position range, such that the linkage refrains from adjusting the second dimension when the magnitude of the second force is outside the second magnitude range, and such that the linkage refrains from adjusting the second dimension when the angular position of the rotatable member is outside the second position range.

26. The method in accordance withclaim 22 wherein the first and second forces are applied to the footpad in substantially orthogonal directions.

27. The method in accordance withclaim 22 wherein the first and second dimensions are in substantially orthogonal directions.

28. The method in accordance withclaim 22 wherein the first dimension of the closed path defines a stride length of the user's foot, and

wherein the second dimension of the closed path defines a stride height of the user's foot.

29. An exercise apparatus comprising:

a frame,

a right footpad for supporting a user's right foot,

a left footpad for supporting the users left foot,

a linkage for coupling the right and left footpads to the frame and for guiding the right and left footpads in a closed pats in response to forces applied to the right and left footpads by the user's right and left feet, the linkage including a rotatable member having an angular position indicative of positions of the right and left footpads within their closed paths, wherein the linkage adjusts dimensions of the closed paths of the right and left footpads in response to electrical control signals supplied as inputs to the linkage, and

a control system for monitoring the angular position of the rotatable member, for monitoring the forces applied to the right and left footpads, and for generating the control signals such that the linkage adjusts at least one dimension of the right footpad as a function of monitored force on the right footpad and of the angular position of the rotatable member, and independently adjusts at least one dimension of the left foot pad as a function of monitored force on the left footpad and of the angular position of the rotatable member.

30. The exercise apparatus in accordance withclaim 29 wherein the control system generates the control signals to cause the linkage to increase and decrease the path dimensions of the right and left footpads when it senses particular combinations the angular position and the monitored forces, thereby permitting the user to independently control the dimensions of the paths followed by the right and left footpads by controlling the forces applied to the right and left footpads.

31. The exercise apparatus in accordance withclaim 30

wherein the control system controls the control signals such that the linkage alters the dimension of the closed path of the right footpad when a magnitude of the force on the right footpad is outside a first magnitude range while the angular position of the rotatable member is within a first position range and otherwise refrains from adjusting the dimension of the closed path of the right footpad; and

such that the linkage alters the dimension of the closed path of the left footpad when a magnitude of the force on the left footpad is outside a second magnitude range while the angular position of the rotatable member is within a second position range and otherwise refrains from adjusting the dimension of the closed path of the left footpad,

32. A method for controlling an exercise apparatus having

a frame,

a right footpad for supporting a user's right foot,

a left footpad for supporting the users left foot, and

a linkage for coupling the right and left footpads to the frame and for guiding the right and left footpads in a closed pats in response to forces applied to the right and left footpads by the user's right and left feet, the linkage including a rotatable member having an angular position indicative of positions of the right and left footpads within their closed paths, wherein the linkage adjusts dimensions of the closed paths of the right and left footpads in response to electrical control signals supplied as inputs to the linkage,

the method comprising the steps of

a. monitoring the angular position of the rotatable member,

b. monitoring the forces applied to the right and left footpads, and

c. generating the control signals such that the linkage adjusts at least one dimension of the right footpad as a function of monitored force on the right footpad and of the angular position of the rotatable member, and independently adjusts at least one dimension of the left foot pad as a function of monitored force on the left footpad and of the angular position of the rotatable member.

33. The method in accordance withclaim 1 wherein the control signals cause the linkage to increase and decrease the path dimensions of the right and left footpads when in response to particular combinations the angular position and the monitored forces, thereby permitting the user to independently control the dimensions of the paths followed by the right and left footpads by controlling the forces applied to the right and left footpads.

34. The method in accordance withclaim 33

wherein the control signals cause the linkage alter the dimension of the closed path of the right footpad when a magnitude of the force on the right footpad is outside a first magnitude range while the angular position of the rotatable member is within a first position range and otherwise to refrain from adjusting the dimension of the closed path of the right footpad, and

wherein the control signals cause the linkage alter the dimension of the closed path of the left footpad when a magnitude of the force on the left footpad is outside a second magnitude range while the angular position of the rotatable member is within a second position range and otherwise to refrain from adjusting the dimension of the closed path of the left footpad.

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