FI119967B - Training device and method - Google Patents

Description

EXERCISE DEVICE AND METHOD

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a performance monitoring device for use in sports. The invention is particularly directed to a wrist unit which can be used to measure the intensity of the training. Such a device monitors the athlete's physiological subscriber to provide the athlete with training-related information. The invention also relates to a method for performing exercise training.

Description of Related Art EP 1245184 discloses a heart rate monitor having a digital display comprising panels for plotting the highest and lowest heart rate values. The highlighted portion of the slider bar moves between the highest and lowest values to represent the current heart rate of the user of the device. The heart rate is also displayed numerically at the corner of the screen. The device is limited to indicating only the upper and lower limits of the heart rate. If no part of the slider is highlighted, the user must check the heart rate using the numeric representation. If the linear scale 20 of the slider is extended, the accuracy will decrease to an unusable level due to the limited accuracy and size of the digital displays.

US 5876346 describes a vessel locating device which also functions to display the heart rate as a linear graph.

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EP 0761163 and EP 0842 635 describe another method for displaying heart rate monitors for heart rate monitors. The display has a graphical pulse bar and a numeric pulse representation.

WO 90/00366 describes a numerical display in which the lower heart rate limit, the upper limit of the heart rate 30 and the respective heart rate are represented as numbers.

2

In many prior art devices, setting the upper and lower heart rate limits is extremely difficult. In order to set limits, the user often has to go to the right menu of the device and tap on the setting with the "increase and decrease value" buttons on the device. 5 Because of this, this is often omitted before the start of the exercise, when the usable heart rate limiting function of the device is not used.

In addition, prior art solutions relating to heart rate monitor displays make it difficult for the user to quickly see the current heart rate and heart rate limits. For example, when jogging, the device will inevitably vibrate, which will take a long time to detect the heart rate relative to the limits.

Summary of the Invention

It is an object of the present invention to provide a novel device structure and method which enables a simpler use of the heart rate monitor.

It is also an object of the present invention to provide a device that is readily convertible to assist in performing a particular exercise in a physiologically advantageous manner or in a manner consistent with the individual physical condition of the athlete.

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It is also an object of the present invention to provide a novel method for performing exercise monitoring.

The invention is based on the idea of using an analogue (circumferential motion) wrist unit environment to implement a technical structure that utilizes new visually identifiable combinations of current heart rate reference and heart rate reference reference frequency, whereby the current heart rate is the current heart rate.

3

The heart rate monitor of the present invention comprises a display panel having a current heart rate indicator and an artistic indicator. The current heart rate indicator is sensitive to the signal measured from the user of the device (or the person using the sensor device connected to the device, such as a transmitter belt). The detector is functionally connected to a heart rate-5 scale. The artificial detector has a visually recognizable reference range for heart rate. The heart rate scale and heart rate reference range are adjustable relative to each other.

The method of the present invention comprises monitoring a person's heart rate frequency 10 by visually detecting the current heart rate signal corresponding to the person's heart rate signal and visually detecting the heart rate reference range. The visual indication of the current heart rate is governed by a heart rate scale that is adjustable relative to the heart rate reference range.

By "functional connection" between the current heart rate indicator and the heart rate scale, we mean that the physical placement of the heart rate indicator is linked to an abstract scale that is stored in the device software or hardware and may be adjusted by the device software or hardware. This means that a conversion is needed between the actual heart rate and the position of the heart rate indicator. Scaling can be completely hidden from the user or displayed on a whiteboard.

The detector placement areas may be adapted to discrete or overlapping zones, preferably wholly or partially elliptical zones, typically circular in shape. The current heart rate indicator may comprise a conventional pointer (pointer), a bezel-attached member, or digital segments, such as an LCD or TFT display. The reference area indicator is an arc, disk, or sector of the board printed on the display board or otherwise fixed in this respect. Depending on the embodiment, the heart rate scale and reference range adjustment (adjustment) can be made either manually or automatically. In automatic mode, the heart rate scale and thus the operation of the heart rate indicator relative to the display are modified, for example, on the basis of data collected during previous exercises.

More specifically, the present heart rate monitor is characterized by what is set forth in the characterizing part of claim 1.

The characteristic features of the method are described in claim 16.

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The present invention achieves considerable advantages. In particular, the need to link individual heart rate limits to the absolute heart rate scale whenever setting limits is now redundant. Thus, if the heart rate scale is adjusted, the user does not need to know the reference heart rate values. This is made possible by the new placement and operation of the heart rate monitor and the Artillery 10 men. Thus, the current heart rate indicator and the reference area indicator may operate in complete independence, which is not possible in prior art devices where the respective heart rate value is always displayed in relation to predefined values.

15 From the viewpoint of the average user, important functions needed for the exercise are not lost. On the contrary, the user may concentrate on exercising in the correct heart rate range, listening more closely to his or her body, and paying less attention or even not paying attention to absolute heart rate values. In addition, the time used to program the heart rate monitor can be reduced.

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The construction according to the various embodiments of the invention thus enables simple and clear operation of the device. The user of the device can read the heart rate information associated with the ongoing exercise more clearly and quickly from the relative position of the detectors. The circumference of a circular display is more than three times its diameter. In this case, it is possible to use a pulse rate scale which is three times higher than in prior art devices. This will effectively utilize the area of the device's display panel while allowing for an expandable usable heart rate scale without losing the indication of the desired heart rate level.

30 For most users, the most important aspects of using a heart rate monitor are its ease of setup and readability. However, the implementation and combination of these features 5 has proved difficult. We have found that the modified analogue wristwatch-type (though not necessarily analogue) heart rate and / or heart rate limits are more graphically detectable and sport-detectable. In addition, it provides easy determination of heart rate limits or training zones.

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By rotatable or coaxial arrangements, we mean solutions that allow the heart rate indicator to move substantially around the display area of the device. The detectors may have any form of motion or radius. The detectors may be implemented, for example, by using digital displays or analogue indicators, or a combination thereof. Thus, the term "rotatable" also refers to embodiments in which the detector is movable along a curved path. A rotary motion may be arranged to occur, for example, along an entirely or partially elliptical, preferably circular, path.

In this context, heart rate refers to the actual heart rate or the 15 variables derived from it (exercise intensity). In general, any physiological measurement that is dependent on the athlete's effort and that can be measured with a handheld device or a set of handheld devices (e.g., a chest mount or wrist unit) may be used.

20 In the reference zone, we mean an arbitrary heart rate range. The reference range may thus represent a user-defined lower or upper limit of heart rate between which the user wishes to keep the heart rate during exercise. Alternatively, the reference range may denote a broader heart rate range comprising, for example, visually distinct areas for rest, aerobic exercise, anaerobic exercise, and maximal exercise 25. According to the invention, the reference area is fixedly attached to the board.

The term "digital" and "analog", when referring to a particular heart rate or reference indicator, are commonly used to clarify the visual implementation of the indicators. The term "digital" refers to the use of microparticulate particle motion, for example, liquid crystal displays. pointer-type implementation and other solutions that use a rotating or moving macro level pointer.

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However, the visual implementation of the detectors does not limit the possibilities of electrical or mechanical implementation of the product beyond the panel.

Embodiments of the invention will now be described in more detail with reference to the accompanying drawings.

Brief Description of the Drawings

Figure 1 is a top plan view of an embodiment of the present invention having a digital heart rate indicator and a fixed artificial heart rate indicator.

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Detailed Description of the Invention

Figure 1 illustrates an embodiment in which the heart rate scale is not accurately displayed in numbers, the respective heart rate indicator 51 comprising a display portion having a plurality of display segments arranged substantially radially relative to the display panel, which display segments can be displayed one by one. The articulation detector comprises a curved or sector type (or the like) zone 52 of the display panel indicating the sub-area. The zone is preferably fixed statically to the display panel, for example by painting, printing, coating, gluing or engraving. Training areas can be expressed, for example, in 20 colors. In this case, the lower limit detector symbol 53a and the upper limit detector symbol 53b correspond to the ends of the zone 52. The current heart rate indicator is located within a circular zone located inside, on, or outside the artificial indicator. The current heart rate indicator 51 is adapted to be positioned within the reference zone by adjusting the heart rate scale size represented by the current heart rate indicator 51. This means that the dynamic heart rate range that the device can detect by the current heart rate indicator 51 can be adjusted to correspond, for example, to heart rate from 0 to 220, 50 to 220, 60 to 180, 140 to 170, or any value therebetween.

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Alternatively, as noted above, the current heart rate indicator may comprise a pointer, such as a dial rotatably attached to the center of the display panel.

The choice of heart rate scale described above can be made by the user or the device itself. In a preferred embodiment, the scale is adjusted using the heart rate data collected during previous exercises. In addition, for example, there may be a specific calibration program in which the user is required to perform certain tasks, and the device monitors the heart rate, determines the user heart rate range, and adjusts the heart rate scale relative to the reference range shown. In addition, the scale may depend on the selected 10 training modes, for example, "" Walking Wave "," "Fat Burning Mode", or "" Hard Training ".

An additional display portion 55 may be provided on the display board to indicate, for example, the mean maximum heart rate value, duration of exercise, or other functions typically used in heart rate monitors.

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The functions of the wristop computer may be operated by means of controls which may comprise, for example, knobs, buttons or sliders which are connected to the body of the device or to the display panel. In analogous embodiments, i.e., electromechanical implementations, step motors may be used to move the detectors. In digital embodiments, the control elements are preferably connected to a central unit of the device for transmitting commands to the digital display unit.

It will be apparent to one skilled in the art that the above-described embodiments may be modified and combined without departing from the scope of the present invention. In particular, the visual and mechanical representation and implementation of the display board, as well as the detectors, can be varied widely within the scope of the appended claims.

Claims (18)

A wrist computer having a display panel (50) comprising a current heart rate indicator (51) responsive to a heart rate signal measured from a user of a wrist computer and operatively associated with a heart rate 5 pulse scale, and an articulation detector defining a visually recognizable heart rate (52). characterized in that the reference zone indicator is fixedly fixed relative to the display panel, the respective heart rate indicator is rotatably movable relative to the display panel 10 and the heart rate scale and the reference heart rate zone are adjustable relative to each other. A wristop computer according to claim 1, characterized in that the detectors are at least partially nested within the periphery of the display board. Wrist computer according to one of the preceding claims, characterized in that the articulation indicator comprises a lower level indicator (53a) and an upper level indicator (53b). A wrist computer according to any one of claims 1 to 3, characterized in that the articulation detector comprises an arc or plate-shaped member having visually identifiable indicators for a plurality of areas of physical exercise. A wristop computer according to any one of the preceding claims, characterized in that the respective heart rate indicator comprises a pointer rotatably attached to the center of the display panel. 25 A wristop computer according to any one of claims 1 to 4, characterized in that the current heart rate indicator comprises a display section having a plurality of display segments arranged substantially radially relative to the display panel, which display segments can be displayed one at a time. A wristop computer according to any one of the preceding claims, characterized in that it comprises a first elliptical zone and a second elliptical zone which are nested within the display panel, the first zone comprising a respective heart rate indicator and the second zone comprising an artificial indicator. Wrist computer according to any one of the preceding claims, characterized in that it comprises a rotatable knob for adjusting the heart rate reference range relative to the heart rate scale. 10 A wristop computer according to any one of the preceding claims, characterized in that it comprises a memory for storing heart rate data. The wristop computer according to claim 9, characterized in that it comprises a data communication interface for connecting the wristop computer to the host device for transmitting heart rate data to the host device. Wrist computer according to any one of the preceding claims, characterized in that it comprises means for electrically adjusting the heart rate reference range. 20 The wristop computer according to any one of the preceding claims, characterized in that it comprises a communication interface for connecting the wristop computer to the host device for transmitting the heart rate reference data to the wristop computer. A wristop computer according to any one of the preceding claims, characterized in that the reference area comprises a lower level indicator and an upper level indicator, and the heart rate scale is adjustable such that the lower level indicator indicates a lower heart rate and a higher level indicator indicates an upper and lower heart rate. the upper heart rate is determined by predetermined measurements of the physical characteristics of the wrist computer user. A wristop computer according to any one of the preceding claims, characterized in that it comprises means for manually adjusting the position of the articulator on the display board. A method for monitoring a person's heart rate using a wrist computer, the method comprising detecting a person's current heart rate by a first element (51) in response to a person measured heart rate signal, and detecting a heart rate reference zone (52) by at least one other element. detecting using a heart rate scale which is adjustable relative to each other; and 15. using a heart rate reference indicator which is fixed relative to the display screen and a respective heart rate indicator rotatable relative to the display. Method according to claim 15, characterized in that the detection of the current heart rate is made by rotating a first mechanical element which is attached to the center of the display panel of the wristop computer. Method according to claim 15, characterized in that the detection of the current heart rate is made by displaying segments of the electronic display which are arranged in a circular pattern and which can be displayed one by one. Method according to one of Claims 15 to 17, characterized in that the heart rate scale is adjusted to a reference heart rate range using pre-measured information about a person's physical characteristics.