Patent Document

RELATED APPLICATION 
     This application claims the benefit of prior U.S. Provisional Patent Application Ser. No. 60/066,771 filed Nov. 24, 1997. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates generally to monitoring and controlling therapeutic beds and mattress systems. More particularly, the invention relates to a system and methods for detecting and monitoring the distance between a patient and a reference point on a mattress and for controlling the mattress in relation to such distance. 
     BACKGROUND OF THE INVENTION 
     For years those who suffer from limited mobility due to age, disease or immobilizing physical condition have sought relief from decubitus ulcers, cramping and discomfort as a result of being bedridden for long periods of time. A wide range of therapeutic supports for bedridden patients, such as inflatable mattresses, mattress overlays and mattress replacements, have been made commercially available in the United States. One such support is commercially available from Kinetic Concepts, Inc. (of San Antonio, Tex.) under the “TheraKair” designation, as a mattress which provides pulsating action through inflatable support cushions as described in U.S. Pat. No. 5,267,364. 
     Therapeutic mattresses are often designed to reduce “interface pressures,” which are the pressures that are exerted by a mattress on skin of the patient (or vice versa) while the patient is lying on the mattress. Given time, elevated interface pressures can reduce local blood circulation around the skin and, as a result, may contribute to bedsores and other complications. With inflatable mattresses, as the inflation air pressure decreases, a patient&#39;s susceptibility to encountering elevated interface pressures also tends to decrease, thereby reducing the likelihood that the patient will develop bedsores. 
     A problem with deflation, however, is the increased risk of “bottoming-out”, which is a widely known effect where the upper surface of an air mattress converges and comes into direct contact with the lower surface. Bottoming out can negate much of the benefit of an air mattress by increasing the patient&#39;s pressures at the point of bottoming-out and, therefore, increase the risk of bedsores. Abrupt bottoming-out, such as when the patient is initially positioned on the mattress, could increase the risk of further injury to an already frail, bedridden patient. There has been a long felt need to have an inflatable mattress which self-adjusts the air pressure in inflatable cushions for optimal therapeutic purposes while significantly diminishing the risks of bottoming-out. 
     Some concepts of regulating air supply within a mattress for the prevention of bedsores and some concepts for the mitigation of bottoming-out effects are known. For example, U.S. Pat. No. 4,694,520 describes methods for detecting inadequate inflation while the patient is situated on the mattress. By contrast, the present invention detects the patient not only when positioned on the bed but also before the patient is even placed on the bed, thereby preventing the risks of rapid bottoming-out by “pre-inflating”. 
     U.S. Pat. No. 4,873,737 provides for the detection of mattress thickness to supply a mean air pressure while the patient is situated thereon. 
     U.S. Pat. Nos. 4,745,647 and 4,768,249 provide force activated sensors to detect whether a patient has bottomed-out on a mattress but does not contemplate detecting the patient as the patient nears the bed. 
     U.S. Pat. No. 4,542,547 provides for mattress inflation through the detection of reflected and pulsed light while the present invention, by contrast, detects diffuse light. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to enhance patient care and to overcome the obstacles and inadequacies of the prior art. 
     The present invention includes features and/or components that have been invented or selected for their individual and combined benefits and superior performance as an apparatus and a method for minimizing patient interface pressures by sensing patient distance and, if necessary, adjusting that distance to some predetermined or calculated level to optimize the therapeutic effects of the patient&#39;s mattress. The system is a combination of components and methods that together have new and novel features. Each of the individual components work in association with the others and are optimally mated for performances. 
     The present invention circumvents current laborious requirements of manually adjusting a mattress for optimal therapeutic inflation or allowing a patient to be filly positioned on the bed before sensing means are activated. The present invention offers a unique “hands-free” approach to controlling a mattress&#39;s air supply while a patient is lying thereon. Through the use of a heterodyning proximation detector similar benefits are achieved even before a patient lies upon the mattress. With such benefits there is less need for extra personnel and training costs to operate a mattress&#39;s air supply system. In addition, the present invention further reduces any risks for rapidly bottoming-out as a patient is initially placed on a mattress. Accordingly, the heterodyning proximation detector detects a patient as the patient nears a mattress and allows for air supply in the mattress to be increased before the patient is ever positioned atop the mattress. 
     The heterodyning proximation detector is an improved version of a somewhat obscure musical instrument that had been developed in the United States during the 1920s called a “Theremin”. The present invention improves on the musical instrument&#39;s ability to sense a human&#39;s natural reactance, or electrical characteristics, and applies this improvement to therapeutically regulating an air mattress. The heterodyning proximation detector is effectively an antenna referenced to a conducting plate with a large surface area that variably responds to the dielectric constants of different materials. The heterodyning proximation detector may also be used to control air supply while the patient is on the mattress along with, or separately from, a force-responsive distance sensing apparatus or a light-responsive distance sensing apparatus, thus reducing the risks for gradual bottoming-out as well. 
     Aspects of the present invention feature a force-responsive distance sensing apparatus for continuously determining how high the patient is being supported on the mattress in real-time while the patient is on the mattress. The depth that the patient sinks into the mattress is used for controlling air supply to the mattress. The patient&#39;s height (or depth) distance is represented as variations in height of a compliant, force transmitting member that is placed relative to the mattress. Thus, a change in height of the patient generates a change of force applied to a force sensitive component coupled to the force transmitting member. 
     Other aspects of the present invention relate to a light-responsive distance sensing apparatus using either visible light or infrared radiation. The mattress upon which the patient rests may be physically divided into sections, such as independently inflatable air-cells, or logically divided into sections, where no physical barrier isolates the air inside the mattress. A section, logical or physical, of the mattress&#39;s initial shape becomes deformed in response to a patient being set atop the air mattress. A light emitter and light detector are situated in a fashion such that a deformation in the mattress shape reduces the amount of light that reaches the detector from the emitter, thereby generating a control signal to adjust the air pressure within the mattress accordingly. The preferred embodiments contain certain elements which include, but are not limited to: 
     a frame for supporting a mattress; 
     a therapeutic mattress set upon the frame where both frame and mattress cooperate in tandem to define a therapeutic bed; 
     a controlled air supply for selectively inflating one or multiple air cells upon receiving data relating directly or indirectly to the height of the patient relative to the bottom of the air mattress. 
     In one preferred embodiment, a heterodyning proximation detector is significantly influenced by the reactance of certain objects within a known distance of the detector. Such an embodiment depends on the electrical signature left by the particular dielectric constant of that object and the field pattern of the heterodyning proximation detector. In particular, the heterodyning proximation detector is either a conducting plate or wire referenced to a ground plane that is responsive to a body&#39;s natural reactance and, thus, functions as an antenna. The antenna is variably connected to a tank circuit having a capacitor and a variable inductor. A frequency oscillator is operatively connected to the tank circuit as well. Thus, as a body nears the antenna, the body&#39;s reactance changes the electrical fields induced into the antenna, resulting in a change in the natural frequency of the oscillator. Accordingly, the frequency signal ultimately generated by the heterodyning proximation detector is used by control circuitry to create a signal which, in turn, controls a blower or regulating valve. The blower is then connected to at least one of the air cells or sections that comprise the mattress. Another embodiment of the apparatus contemplates an array of air cells each with a heterodyning proximation detector and a blower or regulating valve that is responsive to the individual reactance signatures emitted by particular segments of the body. 
     One embodiment includes a force-responsive distance sensing apparatus. The force-responsive distance sensing apparatus comprises a force transmitting member and a force sensing element, which might be a force-sensitive resistor, piezoelectric crystal, or the like, coupled with the force transmitting member. In operation, the force-responsive distance sensing apparatus is placed relative to the mattress so that it is responsive in real-time to the compressive forces that are continuously generated by the patient when the patient is on the mattress. When a patient lying on the mattress has compressed it to the point of bottoming, the force transmitting member is subjected to the maximum amount of loading that is exerted by the patient on the mattress, whereas an uncompressed, fully inflated mattress signifies minimum or no loading on the force transmitting member. In turn, a force sensing element that is coupled to the force transmitting member detects a range of height distance in real-time as a variable range of compression exerted thereon by the force transmitting member. However, compression of the force transmitting member is not necessarily linearly scaled between the maximum and minimum distances of the patient relative to frame; e.g., compressive forces from the force transmitting member might not be generated until the mattress thickness is compressed to some predetermined ratio of the original thickness. 
     Ultimately, a resulting signal from the force sensing element that is related to the compressive forces exerted on the element of the force transmitting member is sent to a controller and compared to a preset calibrating signal. The signal is then converted into a control signal which is sent to a blower or regulating valve. The controller might also be set to work with a microprocessor to store and compare various voltage values. 
     One embodiment includes a light-responsive distance sensing apparatus. The light-responsive distance sensing apparatus comprises a deformable container, inflatable chamber, or the like, having a sealed inner surface that is constructed of light diffusing material. A light emitter and a light detector are attached to the air cell at different locations. In operation, as a patient is set atop the air mattress, the initial shape of the air cell becomes deformed due to the compressive forces exerted by the patient thereon. Thus, any deformation of the container&#39;s inner surface between the light emitter and light detector would scatter light so that, ultimately, less light would be received and detected by the light detector than what light was initially emitted when the air cell was not subject to compressive forces. The resulting output signal from the light detector is sent to a controller and compared to a calibrated reference signal. The controller may then emit a control signal that indicates a significant disparity in the air supply within that air cell or mattress section to a blower or regulating valve to increase air supply. 
     One particular embodiment provides a therapeutic mattress for controlled support of a patient, the mattress comprising at least one inflatable chamber having a first translucent portion for the introduction thereto of light energy and a second translucent portion for the passage therethrough of light energy; a source of light energy adapted to introduce light energy through the first translucent portion into the interior of the inflatable chamber; and a receiver of light energy adapted to receive light energy through the second translucent portion from the interior of the inflatable chamber, the receiver being adapted to generate a signal indicative of the quantity of light so received. The first and second translucent portions are preferably disposed on opposing sides of the inflatable chamber. The inflatable chamber also has one or more pouches to secure the source and/or the receiver to the chamber. Preferably, the pouch also has a releasable closing to facilitate insertion and removal of the source and/or receiver. The pouch optionally also has an opaque portion to conceal the source and/or receiver secured within the pouch and a reflective portion to facilitate the transfer of light energy through the chamber. Cushioning material, such as foam, plastic, or cloth batting, is optionally disposed within the inflatable chamber to provide extra support cushioning to the patient. The chamber optionally also includes an air permeable portion to facilitate a gradual flow of air out of the chamber, and a water permeable portion to draw moisture away from the patient. 
     Another embodiment provides a therapeutic mattress for controlled support of a patient, the mattress comprising a plurality of inflatable chambers each having a light-scattering inner surface; a first of the inflatable chambers having a first light emitter and a first light detector; a second of the inflatable chambers having a second light emitter and a second light detector; and first and second pouches adjacent opposite sides of each of the first and second inflatable chambers. The first light emitter is disposed within the first pouch of the first chamber and is adapted to introduce light energy, preferably infrared light, into the interior of the first chamber. The first light detector is disposed within the second pouch of the first chamber and is adapted to receive light energy from the interior of the first chamber and generate a signal indicative of the quantity of light energy received. The second light emitter is disposed within the first pouch of the second chamber and is adapted to introduce light energy into the interior of the second chamber. The second light detector is disposed within the second pouch of the second chamber and is adapted to receive light energy from the interior of the second chamber and generate a signal indicative of the quantity of light energy received. Furthermore, the mattress is provided with a source of pressurized fluid in communication with the first and second inflatable chambers, the source being adapted to control inflation of the first chamber according to the signal generated by the first light detector, the source being further adapted to control inflation of the second chamber according to the signal generated by the second light detector. Inflation of the first and second inflatable chambers is controlled to minimize interface pressures between the therapeutic mattress and a patient lying on the mattress while simultaneously maintaining sufficient air pressure to prevent the inflatable chambers form bottoming out. 
     Other embodiments may include other distance sensing mechanisms either alone or in combination with the heterodyning proximation detector, force-responsive distance sensing apparatus or the light-responsive distance sensing apparatus, adapted to assist in controlling and monitoring the air supply of the mattress. 
     The invention may take the form of a method for regulating inflation within a mattress assembly or overlay. Such a method can be used to better accommodate a wide range of patient body sizes. The preferred method includes the following steps: 
     1. deflating the mattress and measuring and storing the height distance from a heterodyning proximation detector to a patient while the mattress is deflated; 
     2. initiating inflation of the mattress as the patient nears the heterodyning proximation detector; 
     3. placing the patient on the mattress and continuing to increase the air supply of the mattress until fully inflated. 
     4. measuring and storing the output signal or signals from the heterodyning proximation detector, force-responsive distance sensing apparatus, light-responsive distance sensing apparatus, or any combination of these while the mattress is fully inflated with a patient on top of the mattress; 
     5. calibrating the optimal height distance for that particular patient using the stored signals from the deflated and fully inflated positions; 
     6. monitoring and controlling air supply to the mattress based on the determined optimal height distance using the heterodyning proximation detector, force-responsive distance sensing apparatus, light-responsive distance sensing apparatus, or any combination of these. 
     Among those benefits and improvements that have been disclosed, other objects and advantages of this invention will become apparent from the following description taken in conjunction with the accompanying drawings. The drawings constitute part of this specification and include exemplary embodiments of the present invention and illustrate various objects and features thereof. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a perspective, partially cut away, view of the present invention, an apparatus for sensing patient distance, and all of its components. 
     FIG. 2 is a perspective view showing one possible arrangement of a force-responsive distance sensing apparatus have a force sensing element set within a force transmitting member, shown here as a cushion. A heterodyning proximation detector is also set within the force transmitting member and is working in cooperation with the force-responsive distance sensing apparatus. 
     FIG. 3 is a schematic illustration of one method for regulating the inflation of the air mattress with the apparatus shown in FIG.  1 . 
     FIG. 4 is a perspective view showing one arrangement of a light-responsive distance sensing apparatus through the use of light emission and detection. 
     FIGS. 5 and 6 are cross sectional and side views, respectively, of an alternative arrangement of a self-inflating air cell apparatus where light is emitted through a translucent outer surface of the air cell. 
     FIG. 7 shows the deformation of an air cell&#39;s initial shape in response to compressive forces exerted by a patient when positioned on the mattress. FIG. 7 a.  shows an air cell deformation toward one side of the air cell. FIG. 7 b.  shows an air cell deformation toward the center of the air cell. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     As required, preferred embodiments of the present invention are described herein; however, the disclosed embodiments are merely exemplary of the invention that may be embodied in various forms. The figures are not necessarily to scale; some features may be exaggerated to show details of particular components. Specific structural and functional details disclosed herein are therefore not to be interpreted as limiting, but as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the present invention. 
     Referring to the drawings, at least one embodiment of the apparatus and one method of the present invention may be appreciated for sensing patient distance. FIG. 1 shows the preferred embodiment of an apparatus for sensing patient distance  5  where a force-responsive distance sensing apparatus  205  having a force sensing element  70  coupled to a force transmitting member  65  is functionally cooperating with a heterodyning proximation detector apparatus  105 , and a light-responsive distance sensing apparatus  30  to regulate the air pressure within an air mattress  15  accordingly. FIG. 2 illustrates one embodiment of a force-responsive distance sensing apparatus  205  comprising a force sensing element  70  horizontally positioned within a force transmitting member  65 . FIG. 3 illustrates a preferred method for regulating the air flow of an air mattress  15  using data obtained from a heterodyning proximation detector apparatus  105 . FIG. 4 features one embodiment of a light-responsive distance sensing apparatus  30  comprising a light emitter  125  and a light detector  135  positioned at the opposing ends of a deformable inflatable chamber  150 . FIGS. 5 and 6 illustrates an alternative embodiment of a light-responsive distance sensing apparatus  30  incorporating a pliable covering  175  to cover and secure the light emitter  125  and the light detector  135  to the chamber  150 . FIG. 7 shows various exemplary deformation configurations to which a light-responsive distance sensing apparatus  30  might be subjected. With reference to each of these illustrated embodiments, however, it should be understood by those ordinarily skilled in the art that various other apparatus and methods could be incorporated without departing from the scope of the present invention. 
     Referring to FIG. 1, there is shown a patient  10  positioned partially atop an apparatus for sensing patient distance  5  above a patient support surface. As shown, an apparatus for sensing distance  5  of the present invention includes an air mattress  15  which defines a patient support surface, and is preferably supported by a conventional bed frame  25 . Frame  25  typically comprises more than one articulatable section, and is preferably mounted on castors for ease of movement in the hospital environment. To rotate or elevate the patient thereon, frame  25  may include hydraulic lifting mechanisms for raising and lowering portions of the frame  25 , including the articulatable sections of the frame  25 . Frame  25  may further be constructed of radiolucent materials, such as LEXAN, that are ideally suited for taking x-rays. A preferred air mattress  15  includes a series of air cells  31  which define an upper surface  20  and a lower surface  21  of the air mattress  15 . In its preferred embodiment, patient  10  primary support and cushioning is provided by a series of air cells  31 , however, the present invention is operable with an air mattress  15  comprising a single air cell  31 . The upper and lower surfaces  20 ,  21  may be constructed of water permeable material which acts to draw moisture away from the patient  10  and, thus, assist in maintaining a sanitary environment. For therapeutic purposes, air cells  30 ,  31  can be constructed using an air permeable material to facilitate a gradual flow of air through the upper and lower surfaces  20 ,  21  of each air cell  30 ,  31 , and thereby provide patient  10  with an air mattress  15  having a preferred therapeutic air pressure. In accordance with the present invention, each air cell  30 ,  31  receives inflation pressure from at least one blower  40  that is connected thereto by a fluid conduit, not shown, or the like. 
     FIG. 1 illustrates a preferred embodiment of the present invention featuring a heterodyning proximation detector apparatus  105 ; a force-responsive distance sensing apparatus  205 ; and a light-responsive distance sensing apparatus  30 . As shown, the force-responsive distance sensing apparatus  205  includes a force transmitting member  65  and force sensing element  70  contained within at least one air cell  31 . A force transmitting member  65  is preferably constructed of a complaint cushioning material such as, but not limited to, foam, plastic or cloth batting. As will be appreciated, the force transmitting member  65  provides the present invention with a two-fold effect. First, the force transmitting member  65  defines an element of the force-responsive distance sensing apparatus  205  for detecting changes in the height of the upper surface  20  relative to the lower surface  21  as a patient is positioned atop the air mattress  15 . More particularly, changes in the patient  10  distance relative to the lower surface  21  are detected in real-time via a force sensing element  70  which measures a variable range of compressive forces exerted by the force transmitting member  65  in response to the compressive forces of a patient  10  resting thereon. Second, the thickness of the force transmitting member  65  provides an air mattress  15  with extra support cushioning in the event air mattress&#39;s  15  inflation pressure is reduced below that required to prevent the patient from bottoming-out, thus reducing the risk for patient injury. 
     FIG. 2 illustrates the preferred spatial relationship between the force sensing element  70  and the force transmitting member  65  of the force-responsive distance sensing apparatus  205 . As shown, the force sensing resistor  70 , which might be a force-sensitive resistor, piezoelectric crystal, or the like, is coupled to the force transmitting member  65  along a horizontal plane  85 ; however, situating such sensors on other spatial planes is contemplated as well. As will be understood be one skilled in the art, the force transmitting member  65  can be formed using a multiplicity of segmented members, which may differ in size and shape, to allow cooperative ease of movement in tandem with the air mattress  15 . Moreover, at least one force sensing element  70 , which transfers the signal through the control wire  71 , may be coupled to at least one segmented force transmitting member  65  or throughout a non-segmented force transmitting member  65  to provide an array of sensors suited for detecting compressive forces from various parts of the body. The force sensing element  70  may also be placed and coupled to the either the upper or lower surface of the force transmitting member  65 , within the force transmitting member  65 , or generally wherever the height of the patient above the frame  25  is desired to be known. Further illustrated in FIG. 2 is an embodiment of the force transmitting member  65  configured as a trapezoidal prism. It should be understood that other configurations can be used without departing from the scope of the invention. Other chosen configurations, however, should facilitate patient comfort, support and stability. 
     As can be appreciated from FIG. 1, compression of the force transmitting member  65  generates a resulting voltage across the force sensing element  70  which is representative of the compression exerted on the force sensing element  70  by the force transmitting member  65 . Following compression of the force transmitting member  65 , the resulting voltage is delivered to a controller  75  where the received voltage is compared to a preset calibrating signal. Deviations in the voltage signal as compared to the preset calibrating signal are then directed across a buffer amplifier  80  which modifies the voltage signal into a speed control voltage. The speed control voltage is then directed to a blower  40  or fluid regulating valve thereby either increasing or decreasing the rate of inflation air into the air mattress  15 . Controller  75  can also be configured to communicate with a microprocessor  60  which stores and compares various voltage values, and is operable to regulate blower  40  or fluid regulating valve in response to changes in patient height distance. 
     As shown schematically in FIG. 1, a heterodyning proximation detector apparatus  5  includes an antenna  36  connected to a tank circuit and oscillator mock-up  45  which is in communication with detector  50 . In its preferred embodiment, tank circuit and oscillator mock-up  45  comprises a capacitor and variable inductor operatively connected to a frequency oscillator. Frequency signals received by detector  50  are sent through a low pass filter  55  which operates to filter out high frequency signals, and emit only low frequency signals for conversion by a frequency-to-voltage converter  56 . The frequency-to-voltage converter  56  transforms the low frequency signals into a speed control voltage which activates a blower  40  or fluid regulating valve to provide inflation pressure to the air mattress  15 . Detector  50  may also be configured with a microprocessor  60  for storing and comparing various voltage values to provide blower  40  speed control. 
     In use, the heterodyning proximation detector apparatus  5  detects interactions between the electrical field pattern of the antenna  36  and the patient&#39;s  10  electrical signature which is characteristic of that patient&#39;s  10  dielectric constant. More particularly, the tank circuit and oscillator mock-up  45  operates to induce an electrical field within the antenna  36  which is responsive to a patient&#39;s  10  electrical signature characterized by the particular dielectric constant of that patient. Upon interaction with antenna&#39;s  36  induced electrical field, a resulting change in the natural frequency of the oscillator is detected. The altered frequency is sent to detector  50  which functions to compare the altered frequency to a preset reference frequency. Detected alterations in frequency signals are then transmitted through a low pass filter, and the resulting difference frequency is sent to a frequency-to-voltage converter  56  and/or servo control circuit which, in turn, communicates a generated speed control voltage to a blower  40  or fluid regulating valve. 
     The generated heterodyning proximation detector frequency is compared to a frequency generated by a calibrating tank circuit and oscillator for any deviations between the two frequencies via a product detector  50 . A deviation in frequency represents any change in the patient&#39;s relative position from the heterodyning detector apparatus  105  as compared to the calibrating, optimal therapeutic air pressure for the air mattress  15 . The deviation frequency from the product detector  50  is sent through a low pass filter  55  to allow only low frequency signals to pass as preparation for entering through a frequency-to-voltage converter  56 . 
     The preferred method for regulating the inflation of an air mattress  15  of the present invention is shown in FIG.  3 . Initially, air mattress  15  is set to a deflated position  90 . While in a deflated position  90 , a patient is furthest away from the antenna  36  and air mattress  15 . Referring to FIG. 3, the antenna  36  and air mattress  15  are collectively depicted as the heterodyning proximation detector apparatus  105 ; thus, data representing the distance where the patient is furthest away from the heterodyning proximation detector apparatus  105  is recorded at the deflated position  90 . As the patient approaches the antenna  36 , the heterodyning proximation detector apparatus  105  detects the patient and signals blower  40  to begin delivering inflation pressure to the air mattress  15 . This step enables a sufficient amount of inflation pressure to be delivered into the air mattress  15  so as to inflate the air mattress  15  and prevent the possibility of patient bottoming-out as the patient is positioned atop the air mattress  15 . The air mattress  15  continues to inflate to a fully inflated position  95  so long as the patient remains positioned atop the upper surface  20  of the air mattress  15 . After the air mattress  15  reaches a fully inflated position  95 , data representing the patient&#39;s closest distance away from the heterodyning proximation detector apparatus  105  is recorded. The patient&#39;s optimal height distance  100  is then calibrated using the stored distances from the deflated and fully inflated positions  90 ,  95  which are based upon the individual&#39;s reactance as detected by the heterodyning proximation detector apparatus  105 . The air supply is continuously monitored and controlled  110  by the heterodyning proximation detector apparatus  105  to maintain the optimal height distance  100 . As the patient&#39;s distance from the heterodyning proximation detector apparatus  105  increases or decreases, the air supply to the air mattress  15  is accordingly increased  115  or decreased  120  by control means specifically contemplated by this invention or the like. Additionally, other methods would provide a force-responsive distance sensing apparatus  205 , a light-responsive distance sensing apparatus  30  or any other sensing means to cooperate and be included within the heterodyning proximation detector apparatus  105  to assist in controlling and monitoring the air supply of the air mattress  15 . 
     FIG. 4 illustrates one embodiment of the light-responsive distance sensing apparatus  30  of the present invention. The light-responsive distance sensing apparatus  30  comprises at least one inflatable chamber  150  forming an outer chamber surface  195  and a sealed inner chamber surface  200 . In a preferred embodiment, the inner chamber surface  200  is constructed of light diffusing materials, such as polyurethane, that are ideally suited to diffuse light within the inflatable chamber  150 . Such inflatable chambers  150  may be arranged singularly, perpendicular to one another, in parallel or in any other preferred configuration that defines an inflatable air mattress  15  for providing primary cushioning and support. It is preferred that the inflatable chambers  150  be constructed of a flexible and pliable material that is receptive to a wide range of compressive forces, especially those forces generated by a patient positioned atop the upper surface  20  of the air mattress  15 . Though other geometric shapes may be contemplated for the inflatable chamber  150 , FIG. 4 depicts the chamber  150  as having a preferred cylindrical shape. As shown, the chamber  150  is constructed having a light emitter  125  releasably or permanently attached to the light emitter end  130  of the chamber  150  using fastening means, such as adhesives, tape, VELCRO, or any other fastening method known to one skilled in the art. A light detector  135  is attached to the light detector end  140  of the chamber  150  using the various fastening methods known in the art. The light emitter  125  and light detector  135  can be an infrared light emitting diode (IRLED) and a photo-transistor, respectively. However, it should be understood to someone skilled in the art that various other light emitters and detectors can be chosen without departing from the scope of the invention. 
     In use, the chamber  150  of the light-responsive distance sensing apparatus  30  is inflated to an initial preset shape  165 , and the light emitter  125  and light detector  135  are activated to detect any deviation from the chamber&#39;s preset shape. As illustrated in FIG. 4, a chamber deformation  160  between the light emitter  125  and the light detector  135  is caused by compressive forces of the patient  10  when positioned on the upper surface  20  of the air mattress  15 . As shown, chamber deformation  160  causes the inner chamber surface  200  to scatter the emitted light, and, thus, results in less emitted light being received and detected by the light detector  135 . The resulting voltage output from the light detector  135  is transmitted through signal line  100  to a controller  170  which compares the light detector  135  voltage output to a preset calibrating voltage. Any deviation away from the preset calibrating voltage represents a material disparity in air supply within the monitored chamber  150 . As shown in the embodiment of FIG. 4, a microprocessor  60  may be configured along with the controller  170  to store and compare the various voltage values. Where a material disparity in air supply is detected, the controller  170  and/or microprocessor  60  respond by delivering a voltage signal that activates a blower  40  or a regulating valve, not shown, to adjust the air supply accordingly. 
     FIGS. 5 and 6 refer to an alternative embodiment of the light-responsive distance sensing apparatus  30  constructed with a pliable covering  175 . In this embodiment, the light emitter  125  and light detector  135  are situated outside of the outer chamber surface  195  at the light emitter end  130  and the light detector end  140 , respectively. Other embodiments of the light-responsive distance sensing apparatus  30  position the light emitter  125  and light detector  135  within the chamber  150 , embedded along the chamber&#39;s surface or any variation thereof. A pliable covering  175  having an inner surface  185  and an outer surface  180  is mated to the outer chamber surface  195  either along the entirety of the chamber  150  or substantially near the light emitter  125  or the light detector  135 . As shown in FIG. 6, the pliable covering&#39;s inner surface  185  is mated to the outer chamber surface  195  forming a pouch  145  for receiving the light emitter  125  or the light detector  135  therein. In effect, the pouch  145  seals and secures the light emitter  125  and the light detector  135  to the chamber  150  by restricting relative movement therein; and the pouch  145 , with its pliable covering, aesthetically conceals the light emitter  125  and the light detector  135 . Additionally; the pouch  145  may be provided with releasable closings to facilitate either insertion or removal of the light emitter  125  or the light detector  135  into or out of the pouch  145  during maintenance or cleaning. FIGS. 5 and 6 show a chamber&#39;s surface which partially forms a pouch  190  as constructed of either transparent or translucent material to accommodate as well as modify the projection of light from the light emitter  125  to the light detector  135  through the chamber  150 . To further facilitate the transmission of light through the chamber  150 , the inner surface  185  of the pliable covering which partially forms the pouch  145  may be constructed of opaque or reflective material. 
     FIG. 7 shows in detail the chamber&#39;s deformation  160  in response to compressive forces exerted by the patient  10  when the patient  10  is resting on the upper surface  20  of the air mattress  15 . FIG. 7 a.  shows a possible chamber deformation  160  towards the light emitter end  130 . FIG. 7 b.  shows a possible chamber deformation  160  centered between the light emitter end  130  and the light detector end  140  of the chamber  150 . Accordingly, one advantage of the present invention is that a deformation is detectable along the entire length of the light-responsive distance sensing apparatus  30 , and, thus, precludes the need for a vast and costly array of sensors along the length of the chamber  150 . As shown in FIGS. 4 and 5, the light emitter  125  and light detector  135  are preferably situated at the opposing ends of the cylindrical chamber  150 . Positioning the chamber  150  transversely across the frame  25  thus enables the caregiver to obtain patient x-rays along the length of the air mattress  15  without any x-ray interference from the light emitter  125  and light detector  135 . 
     While the description given herein reflects the best mode known to the inventor, those who are reasonably skilled in the art will quickly recognize that there are many omissions, additions, substitutions, modifications and alternate embodiments may be made of the teachings herein. Recognizing that those of reasonable skill in the art will easily see such alternate embodiments, they have in most cases not been described herein in order to preserve clarity.

Technology Category: 4