Treadmill control system

Abstract
A microprocessor based exercise treadmill control system is disclosed which includes various features to enhance user operation. These features include programs operative to: permit a set of user controls to cause the treadmill to initially operate at predetermined speeds; permit the user to design custom workouts; permit the user to switch between workout programs while the treadmill is in operation; and perform an automatic cooldown program where the duration of the cooldown is a function of the duration of the workout or the user's heart rate. The features also include a stop program responsive to a detector for automatically stopping the treadmill when a user is no longer on the treadmill and a frame tag module attached to the treadmill frame having a non-volatile memory for storing treadmill configuration, and operational and maintenance data. Another included feature is the ability to display the amount of time a user spends in a heart rate zone.
Description




FIELD OF THE INVENTION




This invention generally relates to exercise equipment and in particular to exercise treadmills having control systems utilizing microprocessors.




BACKGROUND OF THE INVENTION




Exercise treadmills are widely used for performing walking or running aerobic-type exercise while the user remains in a relatively stationary position. In addition exercise treadmills are used for diagnostic and therapeutic purposes. Generally, for all of these purposes, the person on the treadmill performs an exercise routine at a relatively steady and continuous level of physical activity. One example of such a treadmill is provided in U.S. Pat. No. 5,752, 897.




Although exercise treadmills that operate using a microprocessor based control system have reached a relatively high state of development, there are a number of significant improvements in the program software that can improve the user's exercise experience.




SUMMARY OF THE INVENTION




It is therefore an object of the invention to provide an exercise treadmill having improved user programs.




A further object of the invention is to provide a treadmill having a control panel that includes a standard set of user controls with a second set of quick start user controls that permits the user to select certain predetermined treadmill operating parameters such as speed to initiate a workout or to change to one of the predetermined speeds during a workout.




Another object of the invention is to provide a treadmill having a control panel that includes user controls that permit the user to program custom user workouts which have certain operating parameters such as speed and inclination where the custom workouts have greater flexibility than the standard workouts normally programed in a treadmill.




An additional object of the invention is to permit the user to switch programs while the treadmill is operating by merely pressing a particular program button without having to stop the treadmill and start a new program.




A further object of the invention is to provide an automatic cooldown feature that automatically begins upon conclusion of the user's workout where the duration of the cooldown is determined by the length of time of the user's workout and where the treadmill includes a heart rate management system, the cooldown can be terminated by the user's heart rate reaching 60% of maximal.




Another object of the invention is to increase the frequency of display information on the user display that is relevant to the manner in which the treadmill is being used and to decrease the frequency of the display information that is not relevant.




A still further object of the invention is to provide a user detect feature that can use a detector such as an IR receiver/transmitter to stop the operation of the treadmill in order to overcome the problem of users leaving treadmills before the end of their programs which can result in treadmills continuing to run for a period of time. This feature can be further enhanced by using treadmill operating criteria such as key pad or motor controller activity to determine if a user is on the treadmill.




Yet an additional object of the invention is to provide a frame tag module secured to the frame of the treadmill and that includes a nonvolatile electrically erasable programmable memory chip and a real time clock.




It is also an object of the invention to provide a treadmill with a quick start feature.




Another object of the invention is to provide a display of the amount of time a user spends in a specified heart rate zone.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a perspective view of an assembled exercise treadmill according to the invention;





FIG. 2

is a block diagram of the control system for the treadmill of

FIG. 1

;





FIG. 3

is a plan view quick start/quick speed control including a set of user switches for a quick start feature for use with the control system of

FIG. 1

;





FIGS. 4 and 5

are flow charts illustrating the operation of the quick start/quick speed control of

FIG. 3

;





FIGS. 6 and 7

are flow charts illustrating the operation of a custom workout feature for use with the control system of

FIG. 2

;





FIG. 8

is a flow chart illustrating the operation of the control system of

FIG. 2

to implement a feature whereby the user can select a new workout program while the treadmill of

FIG. 1

is operating in another workout program;




FIGS.


9


and


10


A-B are flow charts illustrating the operation of an automatic cooldown feature for use with the control system of

FIG. 2

;





FIG. 11

is a data flow diagram for a user detect feature for use with the treadmill of

FIGS. 1 and 2

;





FIGS. 12A-C

are flow charts further illustrating the operation of the user detect feature of

FIG. 11

; and





FIG. 13

is a flow chart illustrating the operation of a time in heart rate zone feature for use with the treadmill of FIG.


1


.











DETAILED DESCRIPTION OF THE INVENTION





FIG. 1

shows the general outer configuration of an exercise treadmill


10


, according to the invention. The treadmill includes a control panel


12


having a set of displays


14


; a set of workout program control buttons


16


; a set of operational controls


18


-


22


including a pair of time control buttons


18


, a pair of incline control buttons


20


and a pair of speed control buttons


22


; a numerical keypad


24


; and a stop button


26


. In addition, the treadmill


10


includes such conventional treadmill elements such as a belt


28


, a deck


30


and an inclination mechanism


32


of the type described in U.S. Pat. No. 6,095,951.





FIG. 2

is a representative block diagram of a control system


34


for the treadmill


10


. The control system


34


is generally similar to the treadmill control systems of the type shown in

FIG. 16

of U.S. Pat. No. 6,095,951 and controls an AC motor


38


having a motor controller


36


to propel the belt


28


. The control system


34


uses a microprocessor based system controller


40


to control the control panel displays


14


including a message display


14


, the user controls


16


-


22


and


26


along with the keypad


24


, an optional remote display


42


and a remote keypad


44


. In addition, the control system


34


serves to control a heart rate monitoring system of the type described in U.S. Pat. No. 5,313,487 utilizing a set of pulse sensors


46


and a deck or belt lubrication system


48


of the type shown in U.S. Pat. No. 5,433,679 along with the inclination mechanism


32


. The control system also controls a user detect or sense system


50


.





FIGS. 3-5

illustrate a quick start feature that can be implemented in the control system


34


. In particular, a quick start keypad


52


can be attached to the control panel


12


or some other part of the treadmill


10


. The keypad


52


is provided with a set of three buttons: a walk button


54


, a jog button


56


and a run button


58


that can be used by the user to immediately initiate a workout or change a workout having preferably a predetermined speed, for example corresponding to walk, jog or run. The operational controls


18


-


22


can also be used to set other predetermine workout parameters such as inclination, time, distance or calories. User operation is described in FIG.


4


and operation of the program is described in the flow chart of FIG.


5


. Along with a quick start, as indicated in

FIGS. 4 and 5

, the keypad


52


can be used by the user to immediately implement the predetermined speeds or other workout parameters while another workout is in progress. In addition, it is also possible to use a single quick start button


59


on the control panel


12


in combination with the operational controls


18


-


22


to initiate the quick start feature.





FIGS. 6 and 7

are flow charts describing the logic of a preferred embodiment of a custom workout program that can be implemented in the control system


34


. Generally, this feature permits a user or his trainer to use the control keys


18


-


22


, the keypad


24


and the displays


14


to design and program into the control system


34


a custom workout having greater flexibility than the standard workouts normally programed in a treadmill. For example as described in

FIGS. 6 and 7

, the trainer can define a heart rate workout utilizing the pulse sensors and heart rate management system


46


consisting of a series of segments, up to 30, of a fixed duration in seconds, each segment containing a predetermined target heart rate. As indicated at a block


60


in the flow charts of

FIGS. 6 and 7

, the user can select the custom program mode by pressing a custom button


62


which is one of the program buttons


16


on the control panel


12


. In this case the heart rate management program can be used to control the inclination mechanism


32


of the treadmill


10


thereby regulating the user's heart rate for each interval or segment of the program. Also, custom interval hill workouts can be designed where each segment of the workout represents a different incline of the treadmill


10


. Similarly, custom interval speed workouts can be designed by the trainer where each segment of the workout utilizes a different speed. Here, it is desirable to provide the user with an aural warning over a speaker


64


shown in

FIG. 2

of speed changes to prevent surprise transitions. Thus, it is possible to provide a wide variety of custom workouts where the user or trainer can define a number of workout parameters such as the initial speed, duration of the workout, distance and calories burned.





FIG. 8

is a flow chart illustrating the operation of the control system


34


to execute workout programs where, as indicated a pair of blocks


66


and


68


, the control system


34


also permits the user to switch workout programs on the fly by merely pressing one of the program buttons


16


without having to stop the treadmill


10


and start a new workout program. Specifically, the user can select a new workout program having different parameters including, for example, speed, incline, intervals and heart rate while in the midst of a first workout program.




FIGS.


9


and


10


A-B show in flow chart form the logic of an automatic cooldown feature that can be implemented in the control system


34


. In the protocol described in FIGS.


9


and


10


A-B, cooldown will begin automatically upon conclusion of the user's workout. Here, the duration of the cooldown is determined by the length of time of the user's workout or can also be terminated by the user's heart rate reaching 60% of maximal if a heart rate management program of the type identified above is being used. In addition, cooldown can be initiated by the user at any time by pressing a cooldown button


70


located on the control panel


12


. In the system described in FIGS.


9


and


10


A-B, the cooldown sequence will normally automatically progress each minute except that the user can advance the cooldown by pressing the cooldown button


70


or extend the cooldown by using arrow keys on the keypad


24


.




Another feature of the treadmill


10


is the provision in the system controller


34


to only display information on the user displays


14


that is relevant to the manner in which the treadmill


10


is being used. Because the number of discrete displays on the user displays


14


is limited and non-relevant information can be annoying to a user, it is desirable to provide only that information to the user that is most useful for the particular workout that he is performing at the moment. For example, the treadmill


10


having its incline mechanism


32


set at something other than zero will accumulate and can display on one the displays


14


the total vertical distance the user has climbed during the workout. However, if the treadmill


10


is set at zero inclination, the user might become annoyed with a message on the displays


14


always having a zero reading. Thus, in the preferred embodiment of the invention the system controller


40


of the control system of


34


will be programed to only generate a total climb figure on one of the displays


14


at periodic intervals such as 5 minutes. By the same token, generally only runners are interested in their pace such as minutes per mile, so this information will not be displayed by the system controller


40


on the displays


14


for walkers. Also, calories per hour, watts and mets will only be displayed on one of the displays


14


upon a workload change such as a significant speed or incline change so as to eliminate the same message from being displayed on the displays


14


over and over.





FIG. 11

is a data flow diagram and

FIGS. 12A-C

are flow charts illustrating the logic applied by the system controller


40


to implement a user detect feature for use with the treadmill


10


. In order to overcome the problem of users leaving treadmills before the end of workout programs which can result in treadmills continuing to run for an extended period of time, the treadmill


10


can be provided with a mechanism for stopping the belt


28


that is responsive to various criteria for indicating whether or not the user is on the treadmill


10


. Preferably, all of the various resources of information available to the system


34


are used to control this feature. For example, information can be obtained from the motor controller


36


to determine the load on the motor


38


for a predetermined speed which would indicate the presence of a user on the belt


28


. This information can also include timing of the use of the key pad


24


, the inclination mechanism


32


and use of the pulse sensors


46


. In addition, detectors such as an IR detector


72


, a weight sensor


74


using a load cell, and a foot pressure sensor


76


can be used to infer the presence of a user on the belt


28


. As indicated in

FIGS. 11 and 12C

, combinations of this type of information in combination with information received from the IR receiver/transmitter


72


can be used to optimize the determination of the presence of a user on the belt


28


.




It is also possible to use a detector such as the infrared receiver/transmitter


72


shown in

FIGS. 1 and 2

alone as a user detect mechanism. In the preferred embodiment of this detector, a receiver/transmitter


72


transmits an infrared beam which is amplitude modulated at 40 Khz for 500 μsecs every 500 msec. If a user is on the treadmill belt


28


, some portion of the light will be reflected back to the receiver/transmitter


72


which is sensitive not only to the frequency of the beam but also to the 40 Khz modulation. This provides the system controller


40


with an indication that the user is on the treadmill belt


28


. In this embodiment, when the user leaves the treadmill


10


with the belt


28


still moving and the IR detector


72


does not detect the user, the system controller


40


will cause the treadmill


10


to wait a predetermined time, such as 10 seconds, and then switch to a pause mode. In the pause mode the belt


28


is stopped and a “pause” message is displayed on one of the displays


14


. If there is no user input for another predetermined time to the control system


34


, such as 1 minute, the pause mode will time out and the system


34


will reset. In this mode the system controller


40


will also cause the treadmill inclination mechanism


32


to return the inclination of the treadmill


10


to a zero. It should be noted that types of active detectors other than the IR detector


72


can be used such as transmitter receiver combinations using sound or radio frequencies.




FIGS.


11


and


12


A-C provide a more detailed description of the preferred logic and data flow used in the preferred embodiment of the user detect feature.

FIG. 11

is a data flow diagram that represents the flow of data from various sensors such as the pulse sensors


46


, the keypad


24


, the motor controller


36


and the IR sensor


72


to the system controller


40


in FIG.


1


.

FIGS. 12A-C

illustrate the logic performed by the system controller


40


on this data in implementing the user detect feature. With reference to the diagram of

FIG. 11

, the pulse sensor


46


and the keyboard


24


are periodically monitored, as shown by at a data circle


78


and a data circle


80


for example every one second as indicated by a dashed line


82


and a dashed line


84


respectively. An indication that the user is operating the treadmill


10


based on the information in the data circles


78


and


80


is transmitted, as illustrated by a line


82


and a line


88


, to a data circle


90


representing the user detect logic or “monitor user presence” and is implemented in the system controller


40


. This user detect logic as indicated by the monitor user presence circle


90


in

FIG. 11

is described in more detail in connection with FIG.


12


C and is triggered every one second as indicated by a dashed line


92


.




Similarly, the motor controller


36


is monitored as indicated by a data circle


94


at periodic intervals such as every one second as indicated by a dashed line


96


. The object of monitoring the motor control is to determine if the load on the motor


36


reflects the presence of a user on the belt


28


. For example, if there is a user on the belt


28


, it will take more energy to move the belt


28


for a given speed which will be reflected in various parameters of the motor controller


36


as it operates to maintain a predetermined or set speed of the motor


38


. In the preferred embodiment, where the motor


38


is an AC motor such parameters as the voltage applied to the motor's armature windings and measurements of motor slip can be used for comparison to a predetermined belt or motor speed either selected by the user or by a workout program being executed by the system controller


40


. It will be understood that the parameters used for this load versus speed comparison will depend upon the type of motor and motor controller being used in the treadmill and that for instance in a DC motor, motor current can be used. Also, in the preferred embodiment other criteria is used in connection with the motor control user presence determination


94


. For example, as illustrated by the criteria in a box


96


, the present incline of the inclination mechanism


32


, inclination mechanism history and speed motor history can be used. This criteria provides an indication as to whether there are other factors that might affect the speed vs load relationship other than a user on the belt


28


. For example, if the incline of the deck


30


has recently changed or is too high or if the motor speed has recently changed, the speed versus load relationship might not necessarily be representative of a user on the belt


28


. As indicated by a data circle


98


, the stability of this criterial is used as a check on the reliability of the motor load versus speed information


94


. This information, as indicated by a set of lines


100


A-C is also used by the motor sense logic


90


.




The preferred operation of the IR detector


72


in determining user presence on the belt


28


is illustrated in FIG.


11


and FIG.


12


A and FIG.


12


B. Overall operation of the IR detector


72


is indicated by a data circle


102


in FIG.


11


and detailed in FIG.


12


A. In this embodiment, the read user sense procedure


102


is called every 250 microseconds and as indicated in a set of decision blocks


104


and


106


a determination is made as to whether the IR LED is on and whether the IR receiver detects a user. If a user is detected, the routine


102


increments a user present history counter


107


as shown at a block


108


. Then as indicated by a decision block


110


and a set blocks


112


and


114


the IR LED


72


A is reset.




Also in the preferred embodiment, at one second intervals, as shown in FIG.


11


and

FIG. 12B

, a monitor user sense procedure indicated by a data circle


116


is called by the system controller


40


as indicated by a dashed line


117


. If as indicated at a decision block


118


the user detect feature indicated by the term “smart stop” in

FIG. 12B

is not enabled, a flag is set to true at a block


120


indicating to the system controller


40


that there is a user present so that the treadmill


10


will not go into the pause mode. A ten second timer indicated at


122


is used with this procedure. If the smart stop feature is enabled and the ten second interval counted by the timer


122


has expired as indicated by a decision block


124


and the user present history counter


107


shows an absence of a user on the belt


28


as indicated by a decision block


126


, the user present flag is set to false at a block


126


otherwise it is set to true at a block


130


. This procedure


116


also resets the ten second timer


122


to ten seconds at a block


130


if the ten second interval has expired and as indicated at a block and resets the user present history counter


107


to zero at a block


134


. In this manner, the monitor user sense routine


116


is able to determine if the IR detector has not detected a user on the belt


28


for a period of ten seconds.




The preferred of the user detect or monitor user sense logic


90


is illustrated in FIG.


12


C. As described above this routine


90


is called every one second by the system controller


40


. First, as indicated at a block


136


, the user present flag is set to true and then the monitor user sense routine


116


is called. Then, as indicated by a series of decision blocks


138


,


140


and


142


the routine


90


checks various treadmill operating parameters including whether hands have been detected on the pulse sensors


46


, if the key pad


24


has been used recently and if the user has changed the incline mechanism


32


or speed recently based on information shown in the box


96


of FIG.


11


. In addition the user sense


116


is checked to determine if a user has been detected on the belt


28


. If the answers to any of these questions is yes, the routine


90


exits. If the answer is no, then the routine


90


checks the motor controller presence likelihood or inference data


98


at a decision box


146


and if it appears that the user is not on the belt


28


, the routine


90


sets the user present flag true at a box and then proceeds to a treadmill pause and reset routine indicated by a box


150


and a dashed line in FIG.


11


. In the preferred embodiment as discussed above, the treadmill


10


will enter the pause mode for one minute and then if there is no further user activity, the system controller


40


will reset the treadmill


10


. However, if the motor controller presence inference data


98


at a decision box


146


can not make an inference that the user has left the belt


28


, the routine


90


then first checks at a decision box


152


to determine if the data


98


is too unreliable to use this data by, for example, checking the information in the box


96


. If the information


96


suggests that the motor controller data is too unreliable, the routine


90


then branches to the pause and reset routine


150


. Otherwise, the routine


90


then checks at a decision box


154


to determine if the the motor controller presence inference routine


98


has been disabled and if it has then branches to the pause and reset routine


150


.




Another feature of the treadmill


10


is a frame tag module


77


as shown in

FIG. 2

which is preferably secured to one of the side frames of the treadmill


10


and is adapted to communicate with the system controller


40


. In the preferred embodiment, the frame tag module


77


includes a nonvolatile electrically erasable programmable memory chip (EEPROM)


79


and a real time clock


81


. Included with the EEPROM


79


is a 10 year battery (not shown). Preferably, the clock


81


will be initialized to GMT at the time of manufacture of the treadmill


10


and then set to local time when the treadmill


10


is installed at a customer location and each entry into the EEPROM


79


will be date stamped by the clock


81


. In normal operation, each time the treadmill


10


is powered up, the system controller


40


will retrieve treadmill configuration information from the frame tag module


77


. Included in this information can be such data items as English or metric units for display on the displays


14


, maximum and minimum treadmill belt speeds, language selection as well as accumulated treadmill operational data such as the total time, the total miles, the belt time, the belt miles and the number of program selections. Preferably, when the treadmill


10


is in operation, the system controller


40


will cause data relating to each user workout and operation of the treadmill


10


to be stored in the EEPROM


79


along with all information relating to system errors that might occur. In addition, all information relating to any service procedure is stored in the EEPROM


79


. This information stored in the EEPROM


79


including set up, operational and service data can be displayed on the displays


14


by the system controller


40


so that the history of the treadmill


10


can be read by service personnel. One of the advantages of the frame tag module


77


is if any of the major electrical or mechanical components of the treadmill


10


is replaced, the operational history of the treadmill


10


is not lost. For example, if the control panel


12


containing the system controller


40


, is replaced the treadmill's history will not be lost. The frame tag module


77


can also be replaced without losing the machine's history. In this case, because when the treadmill


10


is powered up, this information is transmitted from the old frame tag module


77


to the system controller


40


, this information can then be transmitted back to the new frame tag module


77


after it has been installed on the treadmill


10


thereby maintaining the treadmill's history with the treadmill


10


.





FIG. 13

is a flow chart illustrating the preferred operation of a time in heart rate zone routine


156


implemented in the system controller


40


of the treadmill


10


. In this feature, the user's heart rate is continuously monitored by the heart rate monitoring system using the pulse sensors


46


while in a preprogramed heart rate workout such as fat burn or cardio workout to provide the user a display on one of the displays


14


of an indication of the time in a predetermined heart rate zone. The user's heart rate zone is determined by comparing the user's actual heart rate with that of the target heart rate as entered by the user on the key pad


24


or calculated for the user by the heart rate management system. After the routine


156


establishes that the workout program is a heart rate workout as indicated at a decision block


158


, the routine


156


then determines at a decision box


160


whether the user has entered his own target heart rate using the key pad


24


. If the user has input his desired target hearts rate, the appropriate heart rate zone is calculated as indicated by a box


162


. In this example, the zone is preferably + or −10 beats from the target heart rate. In the event that the user has not entered his target heart rate, a decision block


164


indicates that the routine


156


determines if the programed workout is a Cardio workout or a fat burn workout and the desired heart rate zone is calculated as indicated by a block


166


or a block


168


. For the fat burn workout, the target is preferably between 60 and 72 percent of the calculated maximal heart rate of (220-age). For Cardio workout, the target is preferably between 72 and 85 percent of the calculated maximal heart rate of (220-Age). After the appropriate heart rate zone has been calculated the routine


156


clears a time in zone clock as shown at a block


170


.




As shown in

FIG. 13

, if the user is in the heart rate zone as determined by a decision block


172


the time in zone clock is incremented and a heart rate in zone flag is set to true as shown by a block


174


, each second is accumulated and can be displayed on one of the displays


14


or a dedicated TIME-IN-ZONE display (not shown.) If the user is in the heart rate zone and has attained his target heart rate previously as indicated by a decision block


176


and then an entry message such as “ENTERING TARGET HEART RATE ZONE” can be displayed on the displays


14


or the dedicated display as shown by a block


178


. It is preferred that visual feedback, via a live heart rate zone chart on the displays


14


be used to graphically show the user his heart rate relative to the heart rate zone. On the other hand, if the user's heart rate was in the zone, but then changes so as to no longer be in the zone as determined at a decision block


180


, an exit message such as “LEAVING TARGET HEART RATE ZONE” is displayed on the displays


14


or the dedicated display as shown at a block


182


and the heart rate in zone flag is set to be false as indicated by a block


184


. In the preferred embodiment, heart rate programs implemented in the system controller


40


with time in zone as the goal can be selected by the user with one of the workout control buttons


16


. Additionally, at the conclusion of a workout, a percentage of the workout time in the heart rate zone can be displayed on one of the displays


14


. This information can also be stored, either in the control system


34


or the frame tag


76


or via a network connection, to provide tracking information so the users can ascertain progress in their workout routines. This information is useful to determine the overall efficiency of the workout time, as it is believed that the most efficient calorie burn may occur while in the heart rate zone. It is also possible to provide real-time recommendations to the user as to how to improve his time in zone efficiency by, for example, instructing the user via the displays


14


to adjust speed, incline, resistance, etc. In addition, it is possible to allow the exercise equipment such as the treadmill


10


, possibly with user acceptance, to automatically perform these adjustments to create a TIME-IN-ZONE MANAGEMENT workout. Although the above system has been described in the embodiment of the treadmill


10


, this feature can equally be used in other types of aerobic type exercise equipment having heart rate management systems such as exercise bikes, step machines and elliptical steppers. Also, the above system can use types of heart rate monitors other than the pulse sensor or heart rate monitor system


46


described above such as monitors that transmit a pulse signal from a pulse sensor belted to a user to a receiver on the exercise apparatus.




It should be noted that the various features described above have been described in terms of their preferred embodiments in the context of the particular treadmill


10


and control system


34


disclosed herein. The manner in which these features can be implemented will depend upon a number of factors including the nature of the treadmill and control system. With respect to programing, there are many different types of hardware and programing languages and techniques that would be suitable for implementing these features that would fall within the scope of this invention.



Claims
  • 1. An exercise treadmill, comprising:a frame structure including two rotatable pulleys, said pulleys being positioned substantially parallel to each other, and a pair of spaced apart longitudinal frame members for providing longitudinal structural support for said frame structure; a motor for rotating a first one of said pulleys; a belt secured over said pulleys so as to move in a longitudinal direction when said first pulley is rotated; an inclination mechanism secured to a first end of said frame structure effective to permit selective inclination of said frame structure by a user; a control system operatively connected to said motor and said inclination mechanism; a control panel secured to said frame structure and operatively connected to said control system wherein said control panel includes at least one display and a set of user controls for controlling the treadmill including said belt speed and said inclination mechanism, to permit a user to operate the treadmill for a workout; and a stop program operatively associated with said control system for stopping the movement of said belt when no user is detected on said belt for a first predetermined amount of time wherein said stop program uses information representing treadmill operating criteria from said control system to detect the user on said belt.
  • 2. The exercise treadmill of claim 1 wherein said operating criteria includes operation of said user controls.
  • 3. The exercise treadmill of claim 1 wherein said operating criteria includes operation of said motor.
  • 4. The exercise treadmill of claim 1 wherein the treadmill includes pulse sensors and wherein said operating criteria includes operation of said pulse sensors.
  • 5. The exercise treadmill of claim 1 wherein said operating criteria includes operation of said inclination mechanism.
  • 6. The exercise treadmill of claim 1 additionally including a detector operatively connected to said control system for detecting the presence of a user on said belt and said stop program utilizes said operating criteria to provide an indication of the absence of the user on said belt in combination with said detector to stop the movement of said belt.
  • 7. The exercise treadmill of claim 1 wherein said first predetermined time is approximately 10 seconds.
  • 8. The exercise treadmill of claim 1 wherein said stop program places the treadmill in a pause mode after said first predetermined time and then resets the treadmill after a second predetermined amount of time.
  • 9. An exercise treadmill, comprising:a frame structure including two rotatable pulleys, said pulleys being positioned substantially parallel to each other, and a pair of spaced apart longitudinal frame members for providing longitudinal structural support for said frame structure; a motor for rotating a first one of said pulleys; a belt secured over said pulleys so as to move in a longitudinal direction when said first pulley is rotated; an inclination mechanism secured to a first end of said frame structure effective to permit selective inclination of said frame structure by a user; a control system operatively connected to said motor and said inclination mechanism; a control panel secured to said frame structure and operatively connected to said control system wherein said control panel includes at least one display and a set of user controls for controlling the treadmill including said belt speed and said inclination mechanism, to permit a user to operate the treadmill for a workout; a detector operatively connected to said control system for detecting the presence of a user on said belt; and a user detect program operatively associated with said control system and responsive to one or more treadmill operating criteria received from said control system for stopping the movement of said belt when said operating criteria indicates no user is detected on said belt for a first predetermined amount of time.
  • 10. The exercise treadmill of claim 9 wherein said operating criteria is selected from the group consisting of use of said user controls, speed of said belt, operation of said inclination mechanism, operation of said motor and operation of a pulse sensor.
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation in part of application Ser. No. 09/651,249, filed Aug. 30, 2000, U.S. Pat. No. 6,626,803, which claims the benefit of Provisional application Ser. No. 60/230,733, filed Sep. 7, 2000.

US Referenced Citations (5)
Number Name Date Kind
4911427 Matsumoto et al. Mar 1990 A
5314391 Potash et al. May 1994 A
5368532 Farnet Nov 1994 A
5820525 Riley Oct 1998 A
6575878 Choy Jun 2003 B1
Provisional Applications (1)
Number Date Country
60/230733 Sep 2000 US
Continuation in Parts (1)
Number Date Country
Parent 09/651249 Aug 2000 US
Child 09/944142 US