1. Field of the Invention
The present invention generally relates to a device which facilitates crawling in infants who are unable to perform the act of locomotion and, more particularly, to a motorized wheeled platform that senses the infant's intent and provides gentle encouragement to assist movement.
2. Background Description
Infants with disabilities, such as cerebral palsy, Down's syndrome, and spina-bifida, have difficulty with early locomotion. Currently, therapists guide the child manually based on their clinical judgment of intention.
It is therefore an object of the present invention to provide a device which facilitates crawling in infants by sensing the infant's intent and assisting movement.
According to the invention, a self initiated prone progressive crawler is designed as a mobility aid to assist an infant in prone locomotion. The infant can be placed in a prone position and secured with loop straps. The arms and legs are unconstrained and are able to reach the floor comfortably. The self initiated prone progressive crawler is a motorized wheeled platform designed to fit a 4 to 24 month old infant (weight range from 15 to 35 lbs). An embodiment of the device has three points of contact with the ground. One point is an industrial trackball, mounted upside down to provide positional and positional derivative data to a controller. It may be located roughly under the chest of the infant and can be highly sensitive to movement. The other points of contact are two DC torque motors which are controlled by the controller. In addition to the positional and positional derivative data provided to the controller, the controller may also receive data from four equally spaced load cells on a force plate and tn-axial accelerometer gyros attached to the upper and lower extremities of the child. The load cells provide force information between the infant and the device to allow weight shifts to be assessed and used as a control parameter. The accelerometer gyros generate data that provides patterns that can correlated to crawling. These patterns can be used to develop control algorithms for the device.
The foregoing and other objects, aspects and advantages will be better understood from the following detailed description of a preferred embodiment of the invention with reference to the drawings, in which:
a-b are top and side pictorial diagrams illustrating an infant attached to the self initiated prone progressive crawler according to the invention;
a-b are bottom and side views of the self initiated prone progressive crawler showing the track ball and the DC torque motor driven wheels which constitute the three-point contact with the ground;
a-b are top and side views of the self initiated prone progressive crawler showing the circular platform attached to the body of the self initiated prone progressive crawler via four equally spaced load cells;
Referring now to the drawings, and more particularly to
The trackball algorithm implemented on the SIPPC controller 42 is illustrated in
The forceplate algorithm implemented on the SIPPC controller 42 is illustrated in
The accelerometer algorithm implemented on the SIPPC controller 42 is illustrated in
The software illustrated in the flow diagrams of
In the passive mode, the DC torque motors 24 and 25 are non-active and the device collects movement data from the trackball 21 and motor encoders 47 and 48 at function block 1001. Force data from the load cells on forceplate 31 is also collected and the center-of-pressure (COP) of the infant is computed and plotted. Accelerometer/gyro data will also be plotted when available.
In the active trackball or movement mode, the DC torque motors 24 and 25 are active and the device responds to input from the trackball 21. The infant must initiate movement with significant amplitude to be registered on the trackball sensor. The SIPPC controller 42 commands the motors to propel the self initiated prone progressive crawler in the direction of the disturbance. The distance and rate of movement are limited and the infant must re-engage the device to continue to get the assist. The process begins in function block 810 where a movement measurement of the self initiated prone progressive crawler is made via the trackball input. A determination is made in decision block 1011 as to whether the self initiated prone progressive crawler has been still long enough. The wait time is selectable by the user. If the wait time is determined to be long enough, the distance and direction are computed in function block 1012; otherwise, the process returns to function block 1010. Next, a determination is made in decision block 1013 as whether the self initiated prone progressive crawler has moved the minimum distance. Again, the minimum distance is selectable by the user. If the movement is the minimum distance, the direction of movement is computed in function block 1014; otherwise, the process returns to function block 1010. Then in function block 1015, power is applied to the DC torque motors 24 and 25 before the process returns to function block 1010.
In the active forceplate mode, the DC torque motors 24 and 25 are active and the device responds to changes in the COP recorded between the infant and the device via the forceplate 31. This mode of operation is equivalent to a “body self initiated prone progressive crawler control algorithm mouse”. When the infant is centered on the device, their COP is typically near the center of the force plate 31. During crawling attempts or extremity movement, the COP will move in proportion to the redistribution of body mass. This occurs in a predictable pattern. Changes in the COP result in motor activation to propel the self initiated prone progressive crawler in the direction of intended movement. Movement assistance is again limited to encourage the infant to stay actively involved in the locomotion process. Sensitivity is controlled by creating a virtual no-assistance zone in the center of the forceplate. The motors will not activate if the COP is within this zone; the smaller the zone, the more sensitive the device to COP movements. The process begins at function block 1020 where the force on the four load cells 32, 33, 34, and 35 under the forceplate 31 is measured. Based on this measurement, the COP is computed in function block 1021. A determination is made in decision block 1022 as to whether the COP is outside the stability circle. The size of the circle can be controlled by the user to increase or increase the sensitivity of the self initiated prone progressive crawler. If the COP is outside the sensitivity circle, the direction of movement is computed in function block 1023; otherwise, the process returns to function block 1021. The direction of movement can be controlled by the user to test the ability of the infant to learn. Based on the computed direction of movement, power is applied to the DC torque motors 24 and 25 in function block 824 before the process returns to function block 1020.
In the active accelerometer mode, the DC torque motors 24 and 25 are again active and the device responds to movement data acquired from the limbs and trunk of the infant. This is accomplished by using tn-axial accelerometer gyros 14 attached to the upper and lower extremities of the child. This type of movement data provides patterns that can correlated to crawling allowing movement of the self initiated prone progressive crawler with “virtual” crawling. The infant does not need to touch the floor or physically move the self initiated prone progressive crawler, the infant only needs to move his or her limbs in space. Because of the variation in data between and within crawling movements, the kinematics would be adjusted to recognize patterns associated with intended crawling activity. Force plate and track ball data may be used to refine this decision algorithm. The process begins in function block 1030 where acceleration of the infant trunk and limbs is measured via the tri-axial accelerometer gyros 14. Next, a temporary adjustment to the pattern is made to normalize the measurement in function block 1031. The pattern of movement is compared to a template in function block 1032. A decision is then made as to the pattern is similar to normal. This determination is based on a statistical comparison of curve-fitting temporally and spatially adjusted data (i.e., time warping). If the pattern is similar to normal, the direction of movement is computed in function block 1035; otherwise, the process returns to function block 1030. Finally, power is applied to the DC torque motors 24 and 25 in function block 1036 before the process returns to function block 2030.
In each of these modes of operation, the control parameters include data collection time, propulsion speed limits, and propulsion distance limits. The safety system includes obstacle detection and system shutdown if control or sensor signal is lost. Referring first to
An example of the system shutdown is shown in
The collected data includes kinematic data, kinetic data and performance data. the kinematic data includes movement time, self initiated prone progressive crawler position, self initiated prone progressive crawler velocity, self initiated prone progressive crawler acceleration, and infant coded observation. The kinetic data includes infant force (i.e., the COP) and infant limb movement (i.e., the tri-axial accelerometer gyros) plus anthropometrics. The performance data collected is the DC motor torque.
Safety has been addressed on several levels.
A novel feature of the invention is the packaging. The controller, motors, and input transducers are all housed on the self initiated prone progressive crawler in a configuration that has a profile low enough for the infant to reach the floor. The only connection between the device and the “outside world” may be a CAT5 (Category 5) computer cable and a power cable. Wireless control may also be employed.
The modes of control are also novel and allow a progression of infant motor-development plans to be implemented. It was designed with research flexibility in mind. It can easily be modified to include future control ideas and combinations of existing control ideas.
The device was designed with research in mind and has been tested on children with Cerebral Palsy (CP). Early data suggests that it does provide facilitated movement. Children with CP do not typically explore their environment like typically developing children.
The device also has utility, not just for children with disabilities, but also for the normally developing child. Facilitating early movement may have some intrinsic benefit to the development of motor coordination and promotes early exploration. The device is unique and innovative in that it does not only serve as an assist or intervention device, but can also be used to gather much needed comprehensive information about how infants with brain lesions learn new motor skills.
Electronic components continue to get smaller and lighter with each generation. The next step is to reduce the need for external power by supplying that power with on-board batteries. The data collection cable could also be replaced with a wireless interface.
While the invention has been described in terms of a single preferred embodiment, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the appended claims.
This application is a Rule 371 application of international application PCT/US2011/37276 filed May 20, 2011, which claims the benefit of U.S. Provisional Application 61/346,527 filed May 20, 2010.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/US2011/037276 | 5/20/2011 | WO | 00 | 1/31/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/146795 | 11/24/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3992023 | Moorer | Nov 1976 | A |
4569532 | Mirkarimi | Feb 1986 | A |
4629950 | Ching | Dec 1986 | A |
5299454 | Fuglewicz et al. | Apr 1994 | A |
5324064 | Sumser | Jun 1994 | A |
5368532 | Farnet | Nov 1994 | A |
5639105 | Summo | Jun 1997 | A |
6019705 | Thom | Feb 2000 | A |
6244991 | Bingham | Jun 2001 | B1 |
6983813 | Wright | Jan 2006 | B1 |
7157875 | Kamen et al. | Jan 2007 | B2 |
7182351 | Williams | Feb 2007 | B2 |
7183910 | Alvarez et al. | Feb 2007 | B2 |
7544172 | Santos-Munne et al. | Jun 2009 | B2 |
8419804 | Herr et al. | Apr 2013 | B2 |
20050278857 | Fairchild | Dec 2005 | A1 |
20110009245 | Flowers | Jan 2011 | A1 |
Number | Date | Country |
---|---|---|
2008015471 | Sep 2010 | MX |
Entry |
---|
Vardhman Sheth, Accelerometer Controlled Robot, Mar. 16, 2012, sites.google.com. |
Number | Date | Country | |
---|---|---|---|
20130144475 A1 | Jun 2013 | US |
Number | Date | Country | |
---|---|---|---|
61346527 | May 2010 | US |