1. Field of the Invention
The invention relates to a performance-monitoring device used in sports. In particular, the invention concerns a wristop device, which can be used for monitoring the intensity of training. Such a device monitors the physiological state of a sportsman and provides training-related data to the sportsman. The invention also concerns a method of carrying out exercise monitoring.
2. Description of Related Art
EP 1245184 discloses a heart rate monitor having a digital display, which comprises panels for showing a lower and higher limit of the heart rate in numbers. A highlighted section of a slide bar is moved between the higher and lower limit to show the current heart rate of the user of the device. The heart rate is also shown in number format in a corner of the display. The device is restricted to showing in an illustrative way only the heart rates between the lower and upper limits. If no section of the slide bar is highlighted, the user has to refer to the number representation of the heart rate. If the linear scale of the slide bar is extended, the resolution degrades to an unusable level due to a limited resolution and size of digital displays.
U.S. Pat. No. 5,876,346 discloses an artery locating device, which has a function of showing heart rate in a linear graphical slide bar.
In EP 0761163, and EP 0842 635 another display method for a heart rate monitor is disclosed. The display has a graphical heart rate bar and a numerical representation of the heart rate.
WO 90/00366 discloses a numerical display having a lower limit of heart rate, a higher limit of heart rate and the actual heart rate shown in numbers.
In many prior art devices, setting of the lower and higher limits for heart rate is very difficult to carry out. In order to be able to set the limits, the user often has to navigate to a correct menu of the device and to tap the setting in by using “increase/decrease value” buttons of the device. The procedure is therefore often left undone in the beginning of an exercise, whereby the useful heart rate limiting function of the device remains unused.
In addition, the prior art solutions related to heart rate monitor displays are such that it is difficult for the user to quickly see the present heart rate and the heart rate limits. When jogging, for example, the device unavoidably shakes, whereby perceiving of the heart rate with respect to the limits takes a long while.
It is an aim of the invention to provide a novel device structure and method that enable simpler use of a heart rate monitor.
It is also an aim of the invention to provide a device, that is easily configurable to assist follow-through of a particular exercise in a physiologically preferable manner or to correspond to the individual physical condition of a sportsman.
It is also an aim of the invention to provide a novel method for carrying out monitoring of training.
The invention is based on the idea of using an analogue-type (circumferential movement-exhibiting) wristop environment for implementing a technical structure, which takes advantage of a novel combination of visually identifiable current heart rate reference indicators and a reference heart rate range defined by the reference indicators, whereby relative adjustment of the scale of the current heart rate and the reference heart rate range is allowed.
The heart rate monitor according to the invention comprises a dial having a current heart rate indicator and a reference indicator. The current heart rate indicator is responsive to a heart rate signal measured from the user of the device (or from a person wearing its associated sensor device, such as a transmitter belt). The indicator is functionally connected to a heart rate scale. The reference indicator exhibits a visually identifiable reference heart rate range. The scale of the heart rate and the reference heart rate range are adjustable relative to each other.
The method according to the invention comprises monitoring the heart rate of a person by visually indicating current heart rate of the person responsively to a heart rate signal measured from the person, and by visually indicating a reference heart rate range. Visual indication of the current heart rate is regulated by a heart rate scale, which is relatively adjustable with the reference heart rate range.
By a “functional connection” between the current heart rate indicator and the heart rate scale, we mean that the physical positioning of the indicator is bound to an abstract scale, which is stored and possibly adjusted by the hardware or software of the device. That is, a conversion between the actual heart rate and the desired position of the heart rate indicator is needed. The scaling can be totally hidden from the user or shown in the dial.
The positioning areas of the indicators can be arranged on the dial on separate or overlapping zones, preferably of fully or partly elliptical, typically of circular shape. The indicators may comprise traditional hands (pointers), Bezel-mounted members or digital segments, such as LCD or TFT displays. The reference range indicator can also be a printed or rotatable arc, disc or sector on the dial. Movement of the reference indicator is not obligatory. Depending on the embodiment, adjustment (fitting) of the heart rate scale and the reference range can be done either manually or automatically. That is, in the manual mode of operation, the user can, for example, set the reference range by manually rotating the reference indicator (or its sub-elements) on the dial, whereby the range is adjusted with reference to the heart rate scale. In an automated mode of operation the heart rate scale, and thus the behaviour of the current heart rate indicator with respect to the dial, is changed depending on, for example, data collected during previous exercises. Alternatively, adjustment of the reference indicator can be automated.
More specifically, the monitor is characterized by what is stated in claim 1.
The method is characterized in claim 20.
Considerable advantages are obtained by means of the invention. In particular, the need of linking individual heart rate limits to an absolute heart rate scale each time the limits are set is made redundant. That is, if the scale of the heart rate is kept constant, the device does need to know the reference range set by the user. On the other hand, if the scale of the heart rate is adjusted, the user does not need to know the heart rate values of the reference range. This is made possible by a novel positioning and functioning of the heart rate and reference indicators. Thus, the current heart rate indicator and the reference range indicator can function totally independently, which is not possible in the prior art devices, as the current heart rate is always presented relative to the preset limits.
From an average user's point of view, no important functions needed in training are lost. On the contrary, the user may concentrate on doing the exercise on the right heart rate area, listen more to his body and give less or no weight to the absolute heart rate values. In addition, also the time used when programming the heart rate monitor before the exercise can be shortened.
Thus, the described structure allows simple and illustrative usage of the device. From the relative position of the indicators, the user of the device can read the heart rate data related to the ongoing exercise more clearly and in less time. The circumference of a round dial is over three times larger than its diameter. This makes it possible to use a threefold extended heart rate scale compared to prior devices. Thus, the dial area of the device is being used in an efficient manner enabling extending the usable scale of the heart rate indicator and still providing the data on the desired heart rate level.
For most users, the most important aspects in utilizing a heart rate monitor are its easy setting up and good readability. However, the implementation and combining of these aspects has proven difficult. We have found, that a modified analogue watch-type (though not necessarily analogue) implementation of the heart rate and/or heart rate limit data is more graphic and more quickly perceivable in sports. In addition, it provides easily adoptable setting up of heart rate limits or training ranges.
By a rotatable or coaxial arrangements, we mean such solutions, which enable movement of the indicators of heart rate and of the reference range essentially around the dial area of the device. The shapes or the radiuses of movement of the indicators can be any. The indicators can be implemented, for example, by using digital displays or analogue pointers, or a mixture of them. Thus, the term “rotatable” includes also such embodiments, where the indicator is extendable along a curved track. The rotational movement can be arranged to take place, for example, along a full or partial elliptical, preferably circular, track.
By heart rate, we mean the actual pulsing frequency or a measure derived from it (training intensity). Generally, any physiological measure depending on the exertion of the sportsman, and which is measurable by a carry-on device or a set of carry-on devices (such as a chest sensor and a wristop device) can be used.
By a reference range, we mean an arbitrary range of variation of the heart rate. The reference range may thus point to user-defined lower and higher limits of heart rate, between which he or she aims to keep his or her heart rate during an exercise. Alternatively, the reference range may point to a broader heart rate range comprising, for example, visually distinguishable ranges for rest, aerobic training, anaerobic training and maximal output training. The range may be movable or adjustable relative to the dial or statically anchored to the dial.
When referring to the current heart rate or reference indicators, the terms “digital” and “analogue” are generally used to clarify the visual realization of the indicators. The term “digital” is to be understood as an implementation utilizing micro-scale movement of particles, such as in LC-displays. The term “analogue” refers to classical hand-type implementations and other solutions taking advantage of rotating or moving macro-scale pointers. However, the visual realization of the indicators does not restrict the possibilities of electrical or mechanical implementations of the product beyond the dial panel.
Next, the embodiments of the invention are described more closely with reference to the attached drawing.
In
In
The reference indicator can also comprise two, three or four independently adjustable members that can be moved relative to the dial and relative to each other manually or automatically. By this fan-like embodiment, a more flexible training zone indicator, where also the sub-ranges can be adjusted independently, can be formed.
The device of
The choice of the heart rate scale discussed above can be made by the user or by the device itself. In a preferred embodiment, the scale is adjusted by using heart rate data collected during previous exercises. There may, for example, be defined a calibration program, during which the user has to perform certain tasks and the device monitors the heart rates, decides a heart rate range suitable for the user and adjusts the heart rate scale in relation to (fits the heart rate scale to) the shown reference range. In addition, the scale can depend on a chosen training mode, such as “walking mode”, “fat burning mode” or “hard training mode”.
An additional display portion 55 can be arranged on the dial for indicating, for example, average of maximum heart rate, duration of training or other functions typically incorporated in heart rate monitors.
The functions of the wristop computer and the indicators can be controlled by using control means, which can comprise, for example, crowns, buttons, or slide switches attached to the body or dial of the device. In analogue embodiments, the control means can be mechanically connected to the indicators for adjusting them. However, in such embodiments, also electro-mechanical implementations, for example, step motors can be used for moving the indicators. In digital embodiments, the control means are preferably connected to a central unit of the device for communicating the commands to a digital display unit. However, the setting of the reference range on the display unit can be also done totally independently of the other functions of the device, because the information of the reference range does not necessarily need to be transmitted to the central unit.
According to an advantageous embodiment, the control means comprises a crown (denoted with a numeral 16, 26 and 36 in
As appreciated by a person skilled in the art, the embodiments disclosed above can be varied and combined within the scope of the invention. In particular, the visual and mechanical representation and implementation of the dial and the indicators can be varied broadly within the scope of the following claims.