Patent Publication Number: US-2001000459-A1

Title: Apparatus and method for relieving motion sickness

Description:
CROSS-REFERENCE  
     1. This application is related to application Ser. No. 09/121,720, filed on Jul. 24, 1998, which is incorporated in its entirety.  
    
    
     
       BACKGROUND OF THE INVENTION  
       2. 1. Field of the Invention  
       3. The present invention relates to a method and apparatus for relieving motion sickness. More particularly, the present invention is related to providing individual sensory signals that correspond to the motion of a craft, or in another aspect, proximity of potential obstacles, so that the individual may use these signals to improve a sense of equilibrium or to avoid collision with the obstacles.  
       4. 2. Discussion of the Background  
       5. Essentially, motion sickness occurs as a result of an unusual motion experience. When a person is unable to predict or anticipate this unusual motion, the person&#39;s equilibrium may be effected. The phenomenon of motion sickness may be derived from a principle researched by Dr. David Winters, a retired University of Waterloo professor, and which is referred to as “The Principle of Indeterminacy.”  
       6. The principle of indeterminacy describes a human&#39;s natural ability to identify changes in the neuromuscular skeletal system and to adapt to a new optimum motion. For example, if a prosthetic leg does not offer comparable function, an amputee will favor the remaining leg. Thus, the residual limb becomes weaker and the remaining leg becomes stronger. The option to utilize the prosthesis or the natural leg represents a conflict, i.e., between walking in a conventional symmetrical manner or favoring the natural leg. The person, without conscious volition, chooses favoring the natural side when the choice is perceived by the human&#39;s body as optimal. Currently, it is not known for certain which senses are most influential in making this choice. However, it is likely that pain and comfort, proprioceptive, vestibular, and ocular inputs affect this choice.  
       7. Similarly, motion sickness results from a conflict between these vestibular, ocular and proprioceptive inputs. For example, conventional wisdom among charter boat operators is that charter boat captains do not get seasick, unless they spend a significant amount of time below deck, whereas captains of cruise ships are known to be somewhat more susceptible to motion sickness. This is because a charter boat captain usually sits high in the cabin, a position from where he can observe quite clearly what the relatively small charter boat is about to experience. Thus, he has accurate visual data which reconciles a conflict between the vestibular, ocular, and proprioceptive inputs. On the contrary, the captain of a large cruise ship cannot see what is taking place immediately in front of the ship&#39;s bow. Thus, a conflict between the vestibular, ocular, and proprioceptive data is not resolved.  
       8. Motion sickness is very costly for many industries. For example, the airline industry loses millions of dollars per year from passengers who are unwilling to travel because they experience motion sickness. The same can be said for cruise ships. In addition, if a person experiences motion sickness while operating a dangerous vehicle, injury or even a loss of life may occur.  
       9. Thus, a need for a device which relieves or prevents motion sickness will have a significant impact on society. One proposed motion sickness device is that described in Ferguson (U.S. Pat. No. 5,161,196). Ferguson discloses positioning an array of sound emitters at the sides of an enclosure and varying the sound levels from selected emitters in response to changes in the enclosure&#39;s movement. To an individual, the sound source is not perceived as rolling with the vehicle but rather is inertially stable while the vehicle rolls relative to the sound source. That is, Ferguson is directed to creating an artificial sound horizon which is acoustically perceivable to the individual and continuously maintaining the sound horizon substantially positionally stationary with reference to a fixed horizon of the enclosure.  
       10. However, one problem with Ferguson is that an artificial sound horizon is created. This artificial sound horizon (i.e., between sound emitters at opposite sides of the enclosure) may cause an individual to experience further motion sickness because a conflict is created between the vestibular, ocular, and proprioceptive inputs and the artificial sound horizon. Further, another problem with Ferguson is that an array of sound emitters (e.g., speakers) placed at specific locations chosen in accordance with a predicted motion of the enclosure are required. That is, the speakers are required to be located in opposite sides of the enclosure.  
       SUMMARY OF THE INVENTION  
       11. Accordingly, an object of the present invention is to provide a novel apparatus and method for relieving motion sickness.  
       12. Another object of the present invention is to relieve motion sickness by presenting a user with at least one sensory signal including an audio signal, a white noise signal, a pink noise signal, a brown noise signal, a popcorn noise signal, or combinations thereof which have a variation in spectral emphasis in proportion to a sensed motion of an object, so that the user may resolve a conflict between vestibular, ocular, and proprioceptive inputs. The variation in spectral emphasis includes, for example, a variation in a bandwidth, a center frequency, and an amplitude of a first range of the sensory signals. Further, the sensory signals may also include display signals presented on a display. The display signals may be presented on the display as display elements having, for example, a shape, a size, an intensity, and a color. For example, the display elements may include a blue square, red circle, green star, etc. In addition, the display elements may have a variation in a display characteristic, such as a variation in a size, a shape, an intensity, and a color of the display elements. The variation in display characteristic is based on the sensed motion of the object. In addition, the sensory signals may include audio tone signals which have a variation in time intervals between successive tone signals. The variation in time intervals is based on the sensed motion of the object.  
       13. Yet another object of the present invention is to provide a device for assisting an individual which suffers from a severe vestibular imbalance by presenting this individual with audio, white noise, pink noise, brown noise or audio tone sensory signals corresponding to a sensed motion of the individual. White noise is a random noise containing all frequencies and sounds similar to the “hiss” noise generated by an FM radio receiver when tuned off station. That is, white noise is a random noise that has a flat frequency spectrum at the frequency range of interest. In addition, pink, brown or popcorn noise signals may also be used. Pink noise is a random noise whose spectrum level has a negative slope of 10 decibels per decade (i.e., any noise with a power spectrum that falls as a power spectrum of 1/f), and brown noise has a power spectrum of 1/f 2 . The name “brown noise” comes from Brownian motion, which is the random motion of small objects in fluids. Ordinary music tends to have a brown power spectrum, whereas white noise tends to sound noisy or busy, and pink noise sounds overly simple. Popcorn noise includes individual events whose magnitude distribution does not have a maximum at zero and is not even symmetric about zero. Popcorn noise includes isolated spikes in the output voltage and the voltage height of spikes has a mean value that is significantly (i.e., by more than a mV) different from zero. The audio tone signals include tone signals separated by time intervals (spaces).  
       14. Still another object of the invention is to provide a device for assisting a blind individual by presenting the individual with audio, white noise, pink noise, brown noise, popcorn noise signals, audio tone signals or some combination thereof, along with a proximity sensory signal to assist the individual in determining their relative position to other objects.  
       15. These and other objects of the present invention are achieved by providing an apparatus which includes a sensor which senses a motion of an object and a sensory converter which converts the sensed motion to corresponding sensory signals. In addition, the sensory signals are presented to a user by using, for example, a transmitter and receiver. Thus, the user receives the sensory signals and is able to resolve a conflict between vestibular, ocular, and proprioceptive inputs via the principle of indeterminancy. The sensory signals may be any one of audio, white noise, pink noise, brown noise, popcorn noise, display signals, audio tones, or any combination thereof. The audio, white noise, pink noise, brown noise and popcorn noise sensory signals have a variation in a spectral emphasis in proportion to the sensed motion. In the case of audio signals, the variation in spectral emphasis includes varying a frequency of, for example, a first signal within a first predetermined range around a first center frequency in proportion to a sensed pitching motion of the object. For the case of white noise, pink noise, brown noise, and popcorn noise signals, the variation in spectral emphasis includes varying, for example, a first frequency range of the noise signals in proportion to a sensed pitching motion of the object. However, in all cases for audio, white noise, pink noise, brown noise and popcorn noise signals, the variation in spectral emphasis may include, but is not limited to, a variation in a bandwidth, a center frequency, and an amplitude of first range of the sensory signals. In addition, the display signals may be presented on a display as display elements which vary in a display characteristic based on the sensed motion of the object. The variation in display characteristic includes a variation in, for example, a shape, a size, a color, and an intensity of the display element. In the case of audio tone signals, the audio tone signals may have a variation in time intervals between successive audio tones based on the sensed motion of the object.  
     
    
    
     BRIEF DESCRIPTIONS OF THE DRAWINGS  
     16. A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:  
     17.FIG. 1 is a perspective view of an apparatus for relieving motion sickness according to the present invention;  
     18.FIG. 2 is a block diagram illustrating the components of an inertia processor device according to the present invention;  
     19.FIG. 3 illustrates a three-dimensional axis with respect to the inertia processor according to the present invention;  
     20.FIG. 4A is a graph illustrating frequencies of audio signals corresponding to vertical, yaw, and pitch motions sensed by the inertia processor shown in FIG. 3;  
     21.FIG. 4B is another graph illustrating frequencies of audio signals corresponding to vertical, yaw, and pitch motions sensed by the inertia processor shown in FIG. 3;  
     22.FIG. 5A is a graph illustrating frequency ranges of a white noise signal corresponding to vertical, yaw and pitch motions sensed by the inertia processor shown in FIG. 3;  
     23.FIG. 5B is another graph illustrating frequency ranges of a white noise signal corresponding to vertical, yaw and pitch motions sensed by the inertia processor shown in FIG. 3;  
     24.FIG. 5C is yet another graph illustrating frequency ranges of a white noise signal corresponding to vertical, yaw and pitch motions sensed by the inertia processor shown in FIG. 3;  
     25.FIG. 5D is still another graph illustrating frequency ranges of a white noise signal corresponding to vertical, yaw and pitch motions sensed by the inertia processor shown in FIG. 3;  
     26.FIG. 6 is a perspective view of the motion sickness apparatus used aboard a ship;  
     27.FIG. 7 is a perspective view of the motion sickness apparatus attached to an individual;  
     28.FIG. 8 is another perspective view of the motion sickness apparatus included in a headphone;  
     29.FIG. 9 is yet another perspective view of the motion sickness device used to project a display signal including display elements on a display;  
     30.FIG. 10 is another perspective view of the motion sickness device used to assist an eyesight impaired individual;  
     31.FIG. 11A is a graph illustrating audio tone signals corresponding to a vertical motion sensed by the inertia processor shown in FIG. 3;  
     32.FIG. 11B is another graph illustrating audio tone signals corresponding to a yaw motion sensed by the inertia processor shown in FIG. 3; and  
     33.FIG. 11C is yet another graph illustrating sensory signals corresponding to a pitch motion sensed by the inertia processor shown in FIG. 3.  
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS  
     34. Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views, and more particularly to FIG. 1 thereof, there is illustrated an apparatus for relieving motion sickness including an inertia processor  2  connected to an external battery  18  and a transmitter  30 . Also shown is a receiver  44  attached to an individual  42  for receiving a sensory signal  33  transmitted by the transmitter  30 . The inertia processor  2  includes a front panel  3  which houses an audio volume control mechanism  4 , a video control mechanism  5 , a white, pink, brown or popcorn noise volume control mechanism  6 , a pitch (x-axis) sensitivity control mechanism  8 , a yaw (y-axis) sensitivity control mechanism  10 , and a vertical (z-axis) sensitivity control mechanism  12 . The inertia processor also includes an appropriate bandpass filter (now shown) to achieve a desired bandwidth of the sensory signals.  
     35. The audio volume mechanism  4  and the white, pink, brown or popcorn noise volume mechanism  6  may be used to adjust the volume of the sensory signal  33  transmitted by the transmitter  30 . The pitch sensitivity mechanism  8 , the yaw sensitivity mechanism  10 , and the vertical sensitivity mechanism  12  may be used to adjust the corresponding sensitivity of the inertia processor  2 . That is, using these sensitivity mechanisms, a user may set the inertia processor  2  to be more or less sensitive in sensing a motion of an object. Also included in the front panel  3  is an LED power indicator  14  which indicates whether the power is on or off. For example, if the power is on, the LED indicator  14  will be a green color. On a side portion of the inertia processor  2  is a power switch  16  used to turn on and off the inertia processor  2 . The inertia processor  2  also includes three RCA autojacks on a rear side of the instrument (not shown) which provide high impedance, low level output for audio, video, white noise, pink noise, brown noise, popcorn noise and audio tone signals.  
     36. The battery  18  includes a negative battery terminal  20  and a positive battery terminal  22  which connect to the inertia processor  2  via battery wires  24  and  26 . In addition, the inertia processor  2  is connected to the transmitter  30  using a communication cable  28 . Alternatively, the inertia processor  2  may be optically connected (e.g., using infrared signals) to the transmitter  30 . The transmitter  30  includes an antenna  32 , a power switch  34 , and a power LED indicator  36 . Also included is, for example, a multichannel control mechanism  38  and a volume control mechanism  40 .  
     37. The control mechanisms (e.g., volume control mechanisms  4  and  6 ) are not limited to the locations shown in FIG. 1. For example, the volume control mechanisms  4  and  6  may be placed on a side or top portion of the inertia processor  2 . Further, the battery  18 , inertia processor  2 , transmitter  30 , and receiver  44  may be included in a single common housing.  
     38. The inertia processor  2  may be mounted or placed on a level (normally level) surface of an object. The inertia processor  2  senses a motion of the object and converts this motion to corresponding sensory signals for presentation to a user. The audio, white noise, pink noise, brown noise, and popcorn noise sensory signals have a variation in spectral emphasis in proportion to the sensed motion. The variation in spectral emphasis includes, but is not limited to, a variation in a bandwidth, a center frequency, and an amplitude of a first range of the sensory signals. For example, if the inertia processor  2  is configured to operate using audio signals, i.e., by connecting the audio output jack of the inertia processor  2  to the transmitter  30 , the variation in spectral emphasis includes varying a frequency of, for example, a first signal within a first predetermined range around a first center frequency in proportion to a sensed pitching motion of the object. Alternatively, if the inertia processor  2  is configured to operate using white, pink, brown or popcorn noise signals, the variation in spectral emphasis includes varying, for example, a first frequency range of the white, pink, brown or popcorn noise signals in proportion to a sensed pitching motion of the object. In addition, if the inertia processor  2  is configured to operate using display signals, the display signals may be displayed as display elements which have a variation in a display characteristic corresponding to the sensed motion of the object. The display elements may include, for example, red, green, and blue colors used in a conventional video display. The red, green and blue colors are altered in proportion to the sensed motion of the object. Finally, if the inertia processor  2  is configured to operate using audio tone signals, the audio tone signals may have a variation in time intervals between successive audio tones based on the sensed motion of the object.  
     39. The sensory signals sensed by the inertia processor  2  are presented to the user  42  using, for example, the transmitter  30  and receiver  44 . The receiver  44  may be, for example, a pocket-sized receiver, in order to receive the sensed sensory signals  33 . The receiver  44  also includes, for example, an earphone  46  so the user may listen to the corresponding sensory signals. The user  42  then uses the sensory signals  33  transmitted by the transmitter  30 , without conscious volition, to resolve a conflict between the vestibular, ocular, and propreoceptive inputs, thereby relieving a sense of motion sickness.  
     40. In addition, it should be noted that FIG. 1 illustrates the sensed sensory signals being presented to the user  42  with a transmitter  30  and receiver  44 . However, it is also possible to present the sensory signals sensed by the inertia processor  2  directly to the user  42  by using an earphone, for example, connected to the inertia processor  2 . That is, the use of a separate transmitter  30  and receiver  44  is not required.  
     41.FIG. 2 illustrates a block diagram of the components contained within the inertia processor  2 . As shown, the inertia processor  2  includes an accelerometer  51 , a first inclinometer  53 , a second inclinometer  55 , a sensory converter  57 , an audio processor  59 , a video processor  61 , a white, pink, brown or popcorn noise processor  63 , and optionally a proximity sensor  65 .  
     42. The accelerometer  51 , and inclinometers  53  and  55  may be those which are commercially available. The accelerometer  51  senses a vertical motion of an object, the first inclinometer  53  senses a yaw motion of the object, and the second inclinometer  55  senses a pitching motion of the object. The sensory converter  57  converts this sensed motion to corresponding sensory signals for presentation to the user. The audio processor  59  communicates the sensory signals as audio signals or audio tones to the transmitter  30 . Similarly, the video processor  61  and noise processor  63  communicate the sensory signals as video signals and white, pink, brown or popcorn noise signals, respectively, to the transmitter  30 . In addition, the inertia processor  2  may include an additional accelerometer and a third and fourth inclinometer so that the inertia processor may detect a motion in at least one of six degrees of freedom. The inclinometers and accelerometers function as a sensor which detect a motion of the object. Further, the inertia processor  2  may optionally include a proximity sensor  65 . The proximity sensor  65  determines relative locations of other objects with respect to the inertia processor  2  (e.g., by using lasers, or capacitive sensor systems). Thus, a blind person may wear the inertia processor  2  including the proximity sensor  65  and receive audio signals corresponding to the determined relative position of other objects. This feature is shown in FIG. 10 and will be discussed later.  
     43.FIG. 3 illustrates a three-dimensional axis with respect to the inertia processor  2  shown in FIG. 2. The accelerometer  51  senses a vertical motion of the object along the vertical axis, designated as the z-axis. The inclinometers  53  and  55  detect inclination changes (i.e., pitching and yawing motions) about the horizontal plane designated as the x-axis and y-axis, respectively.  
     44.FIG. 4A illustrates audio signals in response to motion sensed by the inertia processor  2 . As shown, the inertia processor  2  generates three different audio signals which individually change in frequency in response to a sensed motion. The z-axis frequency tone  50 , which may be centered at 250 Hz, for example, increases in frequency when a positive z-axis motion is sensed and decreases in frequency in response to a negative z-axis sensed motion. The z-axis vertical tone  50  shown in FIG. 4A is at 200 Hz, which represents a decrease of 50 Hz from the center frequency. That is, a negative z-axis motion was sensed by the accelerometer  51 . The y-axis frequency tone  52 , centered at 500 Hz, for example, increases in frequency when the instrument is tilted clockwise (when viewed from the front of the device) about the y-axis. This is referred to as a yaw to the right. In addition, the y-axis frequency tone  52  decreases in frequency when the instrument is tilted counter-clockwise about the y-axis, referred to as a yaw to the left. The y-axis frequency tone  52  shown in FIG. 4A is at 600 Hz, which represents an increase of 100 Hz from the center frequency. That is, a yaw to the right was sensed by the inclinometer  53 . The x-axis frequency tone  54 , centered at 2 KHz, for example, increases in frequency when the instrument is tilted forward, referred to as a forward pitch, and decreases in frequency when the instrument is tilted backwards, referred to as a rearward pitch. Thus, as shown, the x-axis frequency tone  54  has not changed, which indicates the second inclinometer  55  did not detect a pitching motion. In addition, the changes to the tone frequencies are proportional to the sensed motion, that is, the greater the sensed motion, the greater the tone change. However, the proportional relationship is not necessarily linear and may be empirically determined. The representation of the center tone frequencies of 250 Hz, 500 Hz, and 2 KHz are for illustration purposes only and other values may be used.  
     45. For example, FIG. 4B illustrates the z-axis frequency tone  50 , the y-axis frequency tone  52 , and the x-axis frequency tone  54  centered at frequencies of 500, 1000, and 2000 Hz, respectively. The frequency tones increase and decrease in response to a sensed motion, as described in reference to FIG. 4A. Through experimentation, it has been determined that the human ear is particularly sensitive to frequencies around 1000 Hz. Further, it has been determined that the y-axis yaw motion is particularly critical in causing motion sickness. Therefore, in FIG. 4B, the y-axis frequency tone  52  (i.e., y-axis yaw motion) is centered at 1000 Hz.  
     46. Further, FIGS. 4A and 4B correspond to motion sensed in three degrees of freedom. As discussed above, the inertia processor  2  may detect motion in at least six degrees of freedom. Thus, if six degrees of freedom were sensed, it is possible to represent this by six tones rather than three tones.  
     47.FIG. 5A is similar to FIG. 4A but illustrates a white noise frequency spectrum in response to motion sensed by the inertia processor  2 . In addition, as discussed above, pink, brown or popcorn noise signals may also be used. As shown, the spectral component of the white noise frequency spectrum is divided into three frequency ranges. The white noise frequency spectrum includes a z-axis vertical frequency range  60 , a y-axis yaw frequency range  62 , and an x-axis pitch frequency range  64 . The amplitude of these frequency ranges are altered by the inertia processor  2  in response to the sensed motion. A positive z-axis sensation decreases the amplitude of the z-axis vertical frequency range  60 . A negative z-axis sensation increases the amplitude of the z-axis vertical frequency range  60 . A yaw to the right decreases the amplitude of the y-axis yaw frequency range  62  and a yaw to the left increases the amplitude of this range. Similarly, a forward pitch results in a decrease of the amplitude of the x-axis pitch frequency range  64  and a rearward pitch results in an increase in amplitude of this frequency range. In addition, the changes to the amplitudes of the frequency ranges of the white noise are proportional to sensed motion, that is, the greater the sensation, the greater the spectral amplitude change. Again, the proportional relationship is not necessarily linear.  
     48.FIG. 5A illustrates the z-axis vertical frequency range  60 , y-axis yaw frequency range  62 , and x-axis pitch frequency range  64  centered at 200 Hz, 600 Hz, and 2 KHz, respectively. However, these ranges may be centered at other frequencies. For example, FIG. 5B illustrates the z-axis vertical frequency range  60 , the y-axis yaw frequency range  62 , and the x-axis pitch frequency range  64  centered at frequencies of 500 Hz, 1000 Hz, and 2000 Hz, respectively. The amplitude of these frequency ranges are altered by the inertia processor  2  in response to a sensed motion, as described in reference to FIG. 5A. Further, the y-axis yaw frequency range  62  is centered at 1000 Hz for similar reasons as that discussed in reference to FIG. 4B. That is, the yaw motion is particularly critical in causing motion sickness and the human ear is particularly sensitive to frequencies around 1000 Hz.  
     49.FIG. 5C is yet another graph illustrating frequency ranges of a white noise signal corresponding to vertical, yaw, and pitch motions sensed by the inertia processor shown in FIG. 3. In particular, FIG. 5C is similar to FIGS. 5A and 5B except that a center frequency of the z-axis vertical frequency range  60 , y-axis yaw frequency range  62 , and x-axis pitch frequency range  64  shift in response to a sensed motion. That is, the center frequency of the z-axis vertical frequency range  60  (e.g., centered at 500 Hz) increases in frequency when a positive z-axis motion is sensed and decreases in frequency in response to a negative z-axis sensed motion. The z-axis vertical frequency range  61  (illustrated by a dotted line) represents that the z-axis vertical frequency range  60  has been shifted from a center frequency of 500 Hz to a center frequency of 600 Hz. This shift indicates the inertia processor  2  sensed a positive z-axis motion. That is, a positive z-axis motion was sensed by the accelerometer  51 . The center frequency of the y-axis yaw frequency range  62  (e.g., centered at 1000 Hz) increases in frequency when the inertia processor  2  is tilted clockwise (when viewed from the front of the device) about the y-axis (i.e., yaw to the right). In addition, the center frequency of the y-axis yaw frequency range  62  decreases in frequency when the inertia processor  2  is tilted counter-clockwise about the y-axis (i.e., yaw to the left). The y-axis yaw frequency range  62  shown in FIG. 5C is centered at 1000 Hz, which represents a yaw to the right, was not sensed by the inclinometer  53  (i.e., the frequency range did not shift). The center frequency of the x-axis pitch frequency tone  64  (e.g., centered at 2 KHz) increases in frequency when the instrument is tilted forward, referred to as a forward pitch, and decreases in frequency when the instrument is tilted backwards, referred to as a rearward pitch. Thus, as shown, the x-axis pitch frequency range  64  has not changed, which indicates the second inclinometer  55  did not detect a pitching motion. In addition, the changes to the frequencies ranges are proportional to the sensed motion, that is, the greater the sensed motion, the greater the change of the frequency range. The sound level (i.e., amplitude) of each frequency range may also be adjusted as described in reference to FIGS. 5A and 5B.  
     50.FIG. 5D is still another graph illustrating a variation of frequency ranges of a white noise signal corresponding to vertical, yaw and pitch motions sensed by the inertia processor  2 . FIG. 5D is similar to FIGS. 5B and 5C, but a bandwidth of the z-axis vertical frequency range  60 , y-axis yaw frequency range  62 , and x-axis pitch frequency range  64  also shift in response to a sensed motion. That is, based on a detection motion, the bandwidth may increase or decrease. Thus, for the case of FIG. 5D, the variation in spectral emphasis includes a variation in a bandwidth, a center frequency, and an amplitude of a first range of the sensory signals. For example, as illustrated in FIG. 5D, when the inertia processor  2  senses z-axis vertical data indicating a steady state (i.e., normally level) motion, the bandwidth of the z-axis vertical frequency range  60  is a maximum (|z|=max). When the inertia processor  2  senses an increase in the z-axis vertical motion, the bandwidth of the z-axis vertical frequency range  60  decreases (|z|&lt;max). The decrease in the bandwidth of the z-axis vertical frequency range is illustrated as a z-axis vertical frequency range  61 . Therefore, FIG. 5D illustrates an example of adjusting a bandwidth, a center frequency, and a sound level of the z-axis vertical frequency range  60 . Likewise, the y-axis yaw vertical range  62  and the x-axis pitch vertical range  64  may be adjusted.  
     51. Further, the bandwidth of the frequency ranges may be selected different than that shown in FIGS. 5A, 5B,  5 C, and  5 D. In addition, FIGS. 5A, 5B,  5 C, and  5 D correspond to motion sensed in three degrees of freedom. However, as discussed above, the inertia processor  2  may detect motion in at least six degrees of freedom, and accordingly it is possible to represent these six degrees of freedom by using six frequency ranges of the white noise signal. Further, pink, brown and popcorn noise signals may be used rather than white noise signals.  
     52. To operate the device of the present invention, the inertia processor  2  may be mounted or placed on a level (normally level) surface of an object and connected to the transmitter  30 . One example of using the device of the present invention is that shown in FIG. 6. As shown, the inertia processor  2 , battery  18 , and transmitter  30  are mounted securely in a bow of a boat  70 . When the boat  70  moves, the inertia processor  2  senses this motion and converts the sensed motion into corresponding sensory signals. The sensory signals  33  are then transmitted to the receiver  44  which is attached to the user  42 . The user  42  hears the sensory signals  33  using, for example, an earphone  46 . Thus, the user will, without conscious volition, utilize this accurate new data stream to resolve the conflict between the various ocular, vestibular and proprioceptive inputs via the principle of indeterminacy. The sensory signals  33  may be audio, display, white noise, pink noise, brown noise, popcorn noise, audio tones or any combination thereof. An example of using display signals is shown in FIG. 9 and will be described later. Further, an example of using audio tones is shown in FIGS. 11A-11C and also will be described later.  
     53.FIG. 7 illustrates another use of the device according to the present invention. In this example, the inertia processor  2 , battery  18 , transmitter  30 , and receiver  44  are contained in a single common housing  80 . The inertia processor  2  is similar to that shown in FIG. 2, but includes only the first inclinometer  53  and second inclinometer  55 , which detect yaw and pitch motions, respectively (i.e., the accelerometer  51  is not included). Thus, the inertia processor  2  contained in the common housing  80  senses changes in the individual&#39;s motion (i.e., y-axis yaw and x-axis pitch motions), converts this sensed motion to corresponding sensory signals, and presents the sensory signals to the user. Further, the device may be placed at various points on the body to accurately reflect positional changes, such as a plurality of sensors placed along the individual&#39;s spine.  
     54.FIG. 8 illustrates yet another example in which the device of the present invention may be used. In this example, the inertia processor  2 , battery  18 , transmitter  30 , and receiver  44  are included in a headset so that the movement of the head is sensed rather than the movement of the body. The inertia processor  2  is similar to that discussed for FIG. 7 and senses motion in  2  axes (i.e., yaw and pitch). This illustration is particular useful for individuals which have severe balancing problems. In fact, some individuals with a severe vestibular imbalance become nauseated at the slightest movement of their head. This device can assist that individual in reconciling the conflicts between received vestibular and ocular data.  
     55.FIG. 9 illustrates another example in which the device may be used. In this example, the inertia processor  2  senses the motion of an object and converts this sensed motion into first, second and third display signals to be displayed as corresponding first, second and third displayed elements on a video display  90 . The converted display signals corresponding to the sensed motion is output to, for example, a projection camera  91  via the audio jack of the inertia processor  2 . The projection camera  91  projects the display signals as corresponding displayed elements to the video display  90 , which a single user or multiple users may be viewing while being aboard, for example, a ship. The displayed elements may be a variety of colors, each color corresponding to a particular sensed motion. For example, the red, green, and blue colors in a conventional color scheme may correspond to a sensed vertical, yawing, and pitching motion of the object, with the selected colors varying in a display characteristic in proportion to the sensed motion. For example, the red (R) displayed element  93 , green (G) displayed element  94 , and blue (B) displayed element  95  shown in FIG. 9 may vary, for example, in at least one of intensity, pattern, size, and shade of color based on the respective sensed vertical, yawing, and pitching motion of the object. The displayed elements  93 ,  94  and  95  are illustrated in FIG. 9 as circles. However, the displayed elements  93 ,  94  and  95  may be any symbol, such as a star-shaped symbol, a square-shaped symbol, etc. As shown, the blue (B) displayed element  95  has decreased in size based on a sensed vertical motion (for example, due to a negative pitching motion of the ship). Another example of presenting display signals, which have been converted from sensed motions by the inertia processor, may be achieved by displaying a column of display elements on a left portion of a video display and a row of display elements on a bottom portion of the video display. The column of displayed elements may appear to the viewer as moving vertically in either direction, and the row of displayed elements may appear as moving horizontally in either direction. The column of displayed elements may correspond to the sensed vertical motion and the row of displayed elements may correspond to the sensed yawing motion. The speed and direction that the displayed elements move is based on the sensed motion of the ship. In addition, for the sensed pitching motion, a displayed element which includes a circle with a dot in the center may be displayed in a middle portion of the video display. In this case, the circle may become larger or smaller based on a sensed pitching motion of the stem of the boat, whereas the dot in the center may move up or down, for example, based on a sensed pitching motion of the bow of the boat.  
     56. Thus, the individual user or multiple users viewing the display, can use the displayed elements to reconcile a conflict between the vestibular, ocular, and proprioceptive inputs, thus reducing the likelihood of motion sickness. Similarly, a displayed element representing an actual ship, for example, as in a view directly forward from the bow will also accomplish this same conflict resolution.  
     57.FIG. 10 illustrates another example in which the device of the present invention may be used. In this example, the device is used to assist a blind person. Essentially, if one closes their eyes and walks around a room, it is not particularly difficult to maintain a vertical position. Their proprioceptive receptors and to some extent their vestibular receptors may be termed an experimental data base, which allows them to understand where they are relative at least to an upright position. But if an individual has been blind since birth, they would not have access to this experimental data base. The device according to the present invention is used to expand this data base. By verifying where an individual&#39;s body is relative to the ground and other objects, the individual in question could move about with more confidence. Thus, by using the proximity sensor  65  (shown in FIG. 2), the individual will have an added ability to assert their position relative to other objects.  
     58. In more detail, FIG. 10 illustrates a room  100  in which a blind person (not shown) is wearing the inertia processor  2  included in the common housing  80  shown in FIG. 7, for example. Also shown are objects  102  and  104  which may be furniture, another person, etc. Thus, as the individual walks about the room, the proximity sensor  65  transmits, for example, laser signals  106 . The laser signals  106  are then reflected off the objects  102  and  104 . For example, as shown, a reflected signal  108  is reflected off the object  102 . The inertia processor  2  receives this reflected signal  108  and converts it to sensory signals. The sensory signals have a spectral emphasis which varies in proportion to the distance of the sensed objects relative to the blind individual. For example, if the object  102  is very close, a high pitch tone may be generated, whereas if the object  102  in far away, and low pitch tone may be used. The variation in spectral emphasis includes, but is not limited to, a variation in a bandwidth, a center frequency, and an amplitude of a first range of the sensory signals.  
     59.FIGS. 11A-11C illustrate audio tone signals in response to respectively sensed vertical, yaw and pitch motions of an object. For example, as shown in FIG. 11A, the audio tones shown in portion A have a time interval t 1 . Further, the portion B does not contain audio tones and thus the user would not hear any audio tones. The portion C includes audio tones which are separated by a time interval t 2 . The audio tone signals shown in portion A may be 500 Hz and the audio tone signal shown in portion C may be 550 Hz, for example. The audio tone signals in portion A correspond to a negative detected z-axis vertical motion and the tone signals shown in portion C correspond to a positive detected z-axis vertical motion. Thus, as shown in FIG. 11A, the user hears the tone signals in portion A separated by time intervals t 1  which is due to a negative z-axis vertical detected motion. Then as the object achieves a substantially stable position, the user will hear silence which is illustrated as portion B in the figure. That is, the tone signals only occur when a motion of the object is sensed by the inertia processor  2 . Thus, if the object is not moving, the user will not be inundated with tone signals. Further, the tone signals in portion C, which correspond to a positive detected z-axis vertical sense motion, have a smaller time interval t 2  than the tone signals in portion A (time intervals t 1 ). The tone signals in portion C have a shorter time interval based on a larger degree of the detected z-axis vertical motion. For example, if a large z-axis vertical motion is detected, the time interval t 2  is made shorter so that the user will hear more tone signals than if a smaller z-axis vertical motion is detected. Alternatively, the time intervals may be set to be opposite of that discussed above. That is, the tone signals may be set so that the interval therebetween is larger based on a larger sensed motion.  
     60.FIGS. 11B and 11C are similar to FIG. 11A but correspond to y-axis yaw sensed motion and x-axis pitch sensed motion. The tone signals shown in portion D of FIG. 11B may be 1,000 Hz and are separated by a time interval t 3 . The tone signals shown in portion E may be 1,100 Hz are separated by a time interval t 4 . The audio tone signals shown in portion F of FIG. 11C may be 2,000 Hz and are separated by a time interval t 5 . Obviously, alternative frequencies and time intervals can be used for the audio tones. Thus, as shown in FIGS. 11A-11C, as the motion of the object is detected, a plurality of audio tones are intermittently supplied to the user based on the sensed motion of the object.  
     61. In addition, it is to be understood that the audio tones may also be audio messages, such as words. For example, the audio tones may be words, such as “left, left, left . . . right, right, right” that are presented to the user based on the sensed motion of the object. The interval between the words may also vary as that described for the audio tones.  
     62. A method of relieving motion sickness will now be described with reference to FIGS. 1, 3 and  4 . The inertia processor  2  is used for sensing a motion of an object and for converting the sensed motion to corresponding sensory signals. As discussed above, the audio, white noise, pink noise, brown noise and popcorn noise sensory signals have a variation in spectral emphasis in proportion to the sensed motion. In addition, the display signals have a variation in a display characteristic and the audio tone signals have a variation in time intervals between successive audio tones based on the sensed motion of the object. Further, the method of converting includes presenting the sensory signals using, for example, the transmitter  33  and the receiver  44 . In one example, the method of converting includes varying a frequency of a first signal within a first predetermined range around a first center frequency in proportion to a sensed pitching motion of the object, and varying a frequency of a second signal within a second predetermined range around a second center frequency in proportion to a sensed yawing motion of the object. In another example, the method of converting includes varying a spectral emphasis of a first frequency range of white, pink, brown or popcorn noise signals in proportion to a sensed pitching motion of the object, and varying a spectral emphasis of second frequency range of the white, pink, brown or popcorn noise signals in proportion to a sensed yawing motion of the object. The variation in spectral emphasis includes, but is not limited to, a variation in a bandwidth, a center frequency, and an amplitude of a first range of the sensory signals. In addition, the method of converting also includes generating display elements which correspond to the sensed sensory signals. For the case of display signals, the display signals vary in a display characteristic in proportion to the sensed motion of the object. The method of converting also includes generating audio tone signals which correspond to the sensed sensory signals. For the case of the audio tone signals, the audio tone signals have a variation in time intervals between successive audio tones based on the sensed motion of the object.  
     63. Further, the present inventor has determined that low frequency horizontal movements appear to be most related to motion sickness. By providing a device which includes a sensor to detect these movements, and a sensory converter coupled to the sensor, as discussed above, the present invention reduces the effect of motion sickness.  
     64. Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.