Abstract:
An apparatus for use in the activity of freediving, providing the freediver with increased safety and protection in the event of Shallow Water Blackout, incapacitating hypoxia, or other emergency occurring in or under the water, while providing greater reliability of functioning, and comfort of wearing during the activity of freediving.

Description:
BACKGROUND OF THE INVENTION 
       [0001]    1. Field of the Invention 
         [0002]    The present invention generally relates to life-saving equipment used by swimmers and underwater breath-hold divers and, more particularly, to devices and apparatus for use by freedivers* to aid in returning them to the surface and/or maintaining them at the surface in the event of their losing consciousness due to hypoxia, a phenomenon often referred to among freedivers as “Shallow Water Blackout” (SWB). Without some form of rapid and immediate rescue effort, Shallow Water Blackout usually results in death. (*Freedivers are those individuals who venture underwater while holding their breath, and must therefore return to the surface to breathe.) 
         [0003]    2. Description of the Related Art 
         [0004]    Every year well-trained freedivers, who know the risks of Shallow Water Blackout (SWB), die at an alarming and almost predictable rate. All divers know to jettison their weight belts in an emergency situation. Yet, despite this knowledge, most SWB victims are found on the bottom with their (potentially) life saving weight belts still securely buckled in place. 
         [0005]    The reasons behind this counterintuitive fact have been elusive. A recent global poll of freedivers revealed that the population of freedivers is greater than had been thought, and in conjunction, that deaths from SWB are greater as well. 
         [0006]    Below is a table presenting the data gathered by this poll. As the data was collected and tallied, a trend began to emerge; that those who freedive in clearer waters are more apt to experience death from SWB. 
         [0000]    
       
         
               
               
               
             
               
               
               
             
           
               
                   
               
               
                 COUNTRY 
                 FREEDIVERS 
                 SWB DEATHS/YEAR 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 United States- Continental 
                 10,000 
                 3 
               
               
                 United States- Hawaii 
                 5,000 
                 6 
               
               
                 Greece 
                 50,000 
                 6 
               
               
                 Australia 
                 15,000 
                 10  
               
               
                 Italy 
                 12,500 
                 12  
               
               
                 Portugal 
                 3,000 
                 3-5 
               
               
                 New Zealand 
                 1,000 
                 2 
               
               
                 South Africa 
                 8,500 
                 0-1 
               
               
                 France 
                 100,000-300,000 
                  8-10* 
               
               
                   
                   
                 *(In 2003, 
               
               
                   
                   
                 33 French 
               
               
                   
                   
                 freedivers died 
               
               
                   
                   
                 from SWB) 
               
               
                   
               
             
          
         
       
     
         [0007]    The reason or reasons behind the all-to-frequent occurrence of SWB among experienced freedivers has, until recently, defied rational explanation. However, greater attention and careful scrutiny of the physiology and psychology of freedivers have yielded valuable insight. 
         [0008]    Trained freedivers become adept at ignoring their desire to breathe. In addition, freedivers often are intensely focused and concentrating on a goal, be it depth, duration, or the pursuit of game. Add to this the hesitation experienced by many divers when faced with deciding whether to jettison their weight belt, and potentially ruin a day&#39;s diving, or to wait just a bit longer. 
         [0009]    Through their having made thousands of successful freedives, some freedivers become over confident, especially under the influence of increasing hypoxia. One, some, or all of these factors can combine to cause a diver, who did not intend this freedive to be his last, to succumb to the often lethal effects of Shallow Water Blackout. 
         [0010]    Human physiology changes day-by-day and minute-by-minute. What the experienced freediver has grown accustomed to as normal, may simply be beyond his/her ability to survive in special instances. In some cases, blackout occurs without warning. In other cases, the severely hypoxic freediver is incapable of operating his weight-belt quick-release mechanism. It is theorized that as the freediver approaches the end of dive, there occurs a profound shift in their psychology, i.e., the freediver simply can no longer rely on their “internal clock” or whatever physiological/psychological mechanism it is that tells them it is time to ascend to safety. As a result, the freediver misperceives his remaining time underwater, and ventures unknowingly closer to unconsciousness due to SWB. 
         [0011]    Shallow Water Blackout does not often come on gradually. Rather, the freediver often experiences a sudden “lights out”, and falls unconscious. Once unconscious, the opportunities for successful rescue diminish rapidly as minutes pass. 
         [0012]    Others have attempted to reduce the risk of SWB through the use of inflatable belts, vests, or harnesses that could be inflated by a carbon-dioxide (CO 2 ) filled cylinder in case of emergency. Some have gone so far as to connect a spring driven or mechanical timer to an inflatable buoyancy device. The timer would be activated by the freediver upon descent, and would count down during the dive. When the timer reached its end, it would activate the emergency inflation of the buoyancy device. Upon surfacing prior to the timed period elapsing, the freediver could reset the timer for the next dive, thereby providing some measure of protection against SWB. 
         [0013]    These prior attempts have all incorporated mechanical timers of one form or another. Regardless of form, these timers were all relatively constant with regard to the timed period. That is, they possessed little, if any, ability to vary the period of time elapsed. And none presented the individual end user/freediver with the ability to easily and reliably customize the time interval to reflect their own capabilities. 
         [0014]    Despite the immediate appeal of such devices, all they could do is provide the freediver with a false sense of security, in that all prior approaches to the problem of SWB have failed to realistically examine the variety of circumstances under which it occurs. 
         [0015]    None of the prior devices address the fact that, once unconscious, the freediver frequently begins to sink into the depths. By the time a mechanical timer has run out, the freediver is often too deep for the CO 2  cylinders to inflate the buoyancy device sufficiently to return the freediver to the surface. Boyle&#39;s law states that, for any gas at a constant temperature, the volume will vary inversely with the absolute pressure, while the density will very directly with the absolute pressure. 
         [0016]    A simple application of Boyle&#39;s law to these circumstances reveals that, as a freediver descends underwater, the absolute pressure increases, and the volume of gas available for emergency release from a CO 2  cylinder decreases. While the CO 2  cylinder&#39;s volume might have been sufficient at the surface or near-surface depths, it often proves alarmingly incapable of lifting an unconscious freediver from depth. 
         [0017]    In addition, while manual activation of an inflatable device is desirable in an emergency, all of the prior attempts have utilized CO 2  cylinders, which are not refillable by the user. The not insignificant cost of these disposable cylinders raises the operating cost of the device, and thereby creates a disincentive for the freediver to deploy it. In addition, CO 2  inflation devices are mechanical and are highly prone to corrosion problems. If the inflation device&#39;s cylinder cap piercing pin is allowed to become rusted, blunted, or if the CO 2  pressure cap is unusually thick, these devices will not function properly in an emergency. 
       SUMMARY OF THE INVENTION 
       [0018]    The flaws described above and other deficiencies inherent in previous attempts to reduce the danger of Shallow Water Blackout, combined with the fact that freedivers have, so far, refused to adopt any of the products that have been introduced, has led to the development of this unique and revolutionary device. 
         [0019]    The proposed freediving safety apparatus of the present invention provides the freediver with a customized emergency flotation device that will automatically inflate under a number of life-threatening circumstances. If the freediver stays down beyond his personal limit, or descends to an unsafe depth, the device will inflate and quickly return him to the surface in a face up position. If the freediver decides to manually activate the device, presumably in an emergency situation, he may easily do so. The freediver may not deactivate the apparatus unless he is at or near the surface. 
         [0020]    The safety apparatus has an inflatable buoyancy portion, an inflation source, an actuator portion for enabling inflation of the buoyancy portion, and a control unit for activating the actuator portion under appropriate, predetermined circumstances. 
         [0021]    When worn during the regular course of freediving, the safety apparatus is sleek, stylish, and streamlined. The wearer can move through the water unhindered by, and possibly even unaware of its presence. 
         [0022]    The appearance of the apparatus may take the form of a harness or garment similar to a vest, a sleeved shirt, a pair of suspenders, or even a horse collar type or other arrangement. A variety of straps, zippers, hook-and-loop type fasteners, snaps, clips, and other means may be used to secure the apparatus on the freediver. The apparatus must be adequately secure in order to preclude its rising up, or slipping off, the wearer during an emergency ascent. 
         [0023]    The buoyancy portion may consist of one or more inflatable bladders or chambers, positioned so as to aid in bringing an unconscious freediver to the surface in a face-up position. Ample buoyancy should be provided in the chest area, as well as adequate support for the head and neck. 
         [0024]    It is important that the apparatus deliver the freediver to the surface in a face-up, as opposed to face-down, position. In order to have a better chance of recovery, an unconscious freediver must be in a face-up position. If the freediver is to survive, they must be able to draw a breath of air—thus the necessity of being face-up at the surface. If an unconscious freediver is face-down, it will matter little that he has been brought to the surface. 
         [0025]    The buoyancy portion is readily able to be stored in, or retained by, retention or storage devices, such as envelopes, sleeves, or comparable arrangements in order to streamline the apparatus, thereby reducing drag and increasing wearability. While any number of materials can be used for the purpose, stretchable, flexible, and elastic materials like lycra or neoprene are more appropriate for constructing the storage arrangements for the buoyancy portion. If desired, hook-and-loop fastener materials could be used to help retain the buoyancy portion in its storage configuration. 
         [0026]    In its stored configuration, the apparatus may be made a nondescript color such as black, or even camouflage, in order not to interfere with a freediver&#39;s hunting. 
         [0027]    The buoyancy portion may consist of a single or multiple, even redundant buoyancy bladders or chambers in order to provide effective lift and increased fail-safe reliability. In its inflated state, the buoyancy portion may provide additional benefit from materials of highly visible color or pattern, such as bright yellow or orange, to announce the freediver&#39;s position and emergency status. 
         [0028]    The apparatus may also be equipped with a packet or capsule of colored dye or other signaling medium, which would be released either in conjunction with the apparatus&#39;s activation or shortly thereafter. It is desirable that the freediver&#39;s position be made as readily apparent as possible. Visible signals, such as the inflated buoyancy portion, the release of dye markers at or near the surface, or other similar methods can be complemented by the incorporation of an audible alert system into the design of the apparatus. Battery powered beepers or similar can be activated by the control unit upon apparatus activation or shortly thereafter. 
         [0029]    Signaling means may be incorporated into the device to, one at the surface, transmit a signal that could be received by a nearby receiver. This receiver could be the units of other users, or perhaps located aboard a diving vessel, thereby notifying potential rescuers. Or in the event of an emergency, an operator of a vessel could activate a transmitter that could signal all users in the nearby water. 
         [0030]    Once the control unit signals the activator to release the compressed gas into the buoyancy portion, the buoyancy portion of the apparatus inflates and rapidly deploys from its storage envelopes to rush the freediver to the surface. The buoyancy portions may be constructed to selectively expand away from the freediver, in order not to apply compression forces to their body. Stretchable materials may be used to achieve this goal, as may a variety of construction methods including panels, pleats, etcetera. Over-pressure valve or valves may be used to release excess air from the buoyancy portion and thereby prevent over-filling. A manual dump valve may be incorporated in buoyance portion to allow easy and rapid deflation as desired, thereby also permitting re-packing of the apparatus for re-use. 
         [0031]    A significant advantage provided by this safety apparatus is its reusability. The buoyancy portion may be repacked within the storage and retention devices, and the inflation source refilled. The actuator and control unit may be reset, and the apparatus is once again ready for use. 
         [0032]    The inflation source may take a variety of forms. One preferred form is that of a small cylinder for compressed air. Single or multiple cylinders may be used. Resembling miniature SCUBA tank, such a cylinder may be utilized to allow the advantage of being able to recharge the device from a regular SCUBA tank. This ability to easily and conveniently refill the inflation source greatly increases the likelihood that a freediver will elect to manually activate the apparatus in an emergency situation, rather than demonstrate reluctance because of costly replacement CO 2  cylinders required by the prior art. 
         [0033]    The program logic of the device processes data from high pressure sensors to determine the pressure of the compressed gas inflation source. This pressure value, along with the know capacity of the inflation source or tank, is used to determine a maximum depth for which operation of the device will be permitted. If for some reason, the inflation source is not fully refilled to capacity, the reduced pressure will be translated into a reduction in the available buoyancy for emergency inflation. The logic controls of the apparatus may be programmed to calculate, or use a look-up table, to determine the maximum depth at which adequate buoyancy will be available (with perhaps a margin of safety added). The control unit will then reduce the maximum depth allowed as a depth limit (or trigger depth) that may be selected by a user. 
         [0034]    Similarly, the inflation source may be outfitted with a mouthpiece, tube, or comparable device, to permit the freediver to orally inflate the apparatus. This feature would permit a freediver to orally inflate the apparatus in the event that they desire the benefit of additional buoyancy, and serves as an alternate inflation method. 
         [0035]    The actuator portion is situated between the inflation source and the buoyancy portion of the safety apparatus, and is adapted to direct the flow of the inflation source contents to the buoyancy portion. The actuator portion may be equipped with a valve mechanism, a stopper, or other methods of retaining the contents of the inflation source. In addition, the actuator portion can provide a connector appropriate to attach to a SCUBA tank and permit refilling of the inflation source. 
         [0036]    The inflation source may be mounted directly to the actuator portion, or at a distance, connected by an appropriate hose or manifold. In one configuration, the actuator portion mounts directly to the inflation source. In another arrangement, the actuator is positioned alongside the inflation source, and the two are connected by a manifold or hose. 
         [0037]    The control unit may be mounted in a wide variety of locations. One possible arrangement has the control unit located on the freediver&#39;s chest. Another arrangement has the control unit adapted for mounting on the freediver&#39;s wrist or arm, similar to a watch or data console. 
         [0038]    The control unit conducts internal polling of the different components of the apparatus in order to ensure the apparatus&#39;s ability to function properly. Thorough verification of the apparatus&#39;s readiness is essential, and if the internal polling reveals a component or feature that does not check out, then the control unit is programmed to signal the user through a combination of associated alarms, displays, or even lock-outs to prevent the device from being used in a dysfunctional state. 
         [0039]    As an example, if the control unit detects that power supply for the actuator portion is inadequate to ensure the safe functioning of the apparatus, then the control unit could communicate the low power condition through a message on an LCD display, an illuminated LED, or an audible beeping. In addition, if the control unit detects a situation other than fully operational, then the control unit is capable of entering a locked mode to prevent use of a malfunctioning apparatus. 
         [0040]    Should a freediver persist in attempting to use the apparatus while diving, the control unit can be programmed to prevent such action. One example would be a situation where a freediver attempts to continue diving even though the control unit has indicated that the pressure inside the inflation source is insufficient to provide adequate inflation of the buoyancy portion in an emergency. If the freediver persists in wearing the apparatus and enters the water, the control unit can be programmed to trigger the inflation of the apparatus at a very shallow depth, thereby preventing the freediver from continuing to dive with a false sense of security. Similarly, this auto-inflation upon initiation of a dive may be used by the device to prevent a user from attempting to continue diving under circumstances in which the device indicates a deficiency or error. 
         [0041]    The control unit communicates with the actuator portion, providing the necessary monitoring of potentially triggering variables and other necessary signals. Such communication may be achieved through a waterproof direct connection or, preferably, through wireless means. Radio frequency transmitters and receivers, or even infra-red units, may be used to enable communication between the control unit and the other portions of the apparatus. The control unit gathers data from various sources and monitors for the occurrence of conditions which require triggering of the actuator portion and release of the contents of the inflation source. 
         [0042]    The control unit gathers signals from a variety of sensors. The type and number of sensors is determined by the conditions under which the apparatus is intended to operate. Time, depth, inflation source pressure, power supply condition (e.g., battery charge level), blood oxygen saturation level, pulse rate, and more, are all potentially useful candidates. 
         [0043]    Sensors may be located within the control unit, within the actuator portion, or at other remote locations convenient to a particular arrangement of the apparatus. Sensors and associated control units may be located in more than one location, in order to provide redundancy of operation or to simplify presentation or availability of data. The sensors are preferably electronic and solid state, although mechanical sensors may be used. 
         [0044]    One embodiment calls the control unit contains a processor unit, which gathers and analyzes the output from the various sensors. The processor unit compares the sensor outputs to a set or sets of preprogrammed values. Depending upon the algorithms used by the processor and the sensor outputs received, the control unit determines when and whether to trigger inflation of the apparatus, to enter a lock-out mode, or to remain on stand-by. One or more memory chips or other storage means are used to allow storage of, and access to, logic and control instructions, programming, entered data values, sampled data values, dive history data, service information, diagnostic information, error codes, and other user or apparatus data. 
         [0045]    The control unit may be configured to accept input from the user. A variety of buttons, switches, touch screen, or other methods for interfacing with a user may be incorporated. This provides each user/freediver with the ability to customize their own apparatus to accurately reflect their individual diving capabilities. For example, individualized settings for maximum elapsed time and maximum depth may be designated, entered, selected, or changed by the user. As the user desires, perhaps with changing diving conditions or personal preference, the selected individualized values may be changed repeatedly throughout the day, or as often or infrequently as wished. 
         [0046]    In order to ensure reliability, multiple redundant systems are incorporated into the construction of the apparatus wherever possible. It is desirable for the actuator portion and the buoyancy portion to be engineered and constructed with redundant fail-safe mechanisms. The actuator portion should be, in essence, two actuator systems in one unit. Redundant watertight compartments, power supplies, actuation valves, control units, electronics, sensors, and communications systems may be incorporated to provide a high level of redundancy and ensure operability despite failure of significant components. The buoyancy portion may also consist of two systems. In this manner, even if one system were to fail, the back-up unit would be activated, and the apparatus would still function as needed. 
         [0047]    The safety apparatus of the present invention may be programmed by each freediver to reflect their maximum desired safe operating conditions. In so doing, the danger of a “one size fits all” solution is avoided. By programming each device to reflect the diving capabilities and limits of its wearer, the present invention provides the maximum degree of protection available. 
         [0048]    This safety apparatus will automatically begin its preprogrammed time countdown, when it detects that the freediver has descended. Throughout the dive, the apparatus monitors the elapsed dive time and maximum depth. The timer count down continues even as the freediver returns to the surface. It is not uncommon for freedivers to be disoriented or even lose consciousness despite being back at the surface and breathing. For this reason, the apparatus will continue with its countdown until the freediver manually resets the device using a provided disarming means. In a preferred embodiment, this disarming means is provided by a magnetic trigger and corresponding sensor. The trigger may be located in the remote mounted control unit, perhaps worn on the wrist of a user. The corresponding deactivation sensor may be located in a variety of places, but it is preferred to incorporate it into the wearable harness or garment portion of the device for ease of use. In order to disable the device and signal a safe return to the surface, a user must bring the trigger into close proximity of the deactivation sensor. If the deactivation sensor is affixed in the shoulder, arm, or chest area of the apparatus, a user would be required to bring the wrist mounted control unit close to or in contact with the deactivation sensor in order to prevent automatic inflation of the device, and to reset the device for another dive. 
         [0049]    The freediver is locked out from prematurely disarming the device, unless and until they have returned to the surface. This feature precludes a freediver from prematurely disarming the device while underwater. However, manually activated emergency inflation of the unit while underwater or at the surface is available to a user, and may be achieved by depressing a predetermined button for an interval of time, or combination of buttons. 
         [0050]    Should a freediver begin to approach any of the preset limits of this apparatus, a warning will be given for a period of time, in attempt to gain the freediver&#39;s attention prior to automatic inflation. Such warning can take various, and even multiple forms. For example, constant or flashing lights, LEDs, or LCD displayed messages, audible tones, or vibrating pulses are just some of the possibilities. 
         [0051]    In addition to elapsed dive time and maximum depth as variables which may trigger automatic inflation, a variety of other variables may be monitored and used as potential triggers. For example, oximetry (measuring of blood oxygen saturation) levels or rate of change of those levels, could be used to activate inflation. A measuring probe could be attached to the freediver&#39;s finger inside a glove, or attached to the ear, the nose (preferably the ala of the nose) inside the mask, or measurement could occur at other locations. The freediver&#39;s pulse could be monitored, and its rate or rate of change could be used as a trigger. 
         [0052]    The present invention provides for the use of refillable compressed air containers, rather than expensive disposable CO 2  cylinders. Preferably these are small, readily available, compressed air cylinders. In addition, the invention&#39;s design provides means for the air cylinder to be easily refilled from a standard scuba tank. The inflation source may be filled with air or other harmless gas, e.g. nitrox. 
         [0053]    The benefits of a refillable, reusable device should not be discounted. The apparatus of the present invention, once deployed, can easily be re-packed by the freediver, and the cylinder refilled from a scuba tank or other source. These features effectively counter the reluctance of some freedivers to drop their weight belts in an emergency. Many freedivers are reluctant to drop their weight belts, as such action often results in the permanent loss of the weight belt. The weight belts worn by freedivers are often highly customized to suit the individual freedivers&#39; needs and preferences. 
         [0054]    For convenience, comfort, and wearability, the compressed air cylinder(s) may be worn in a variety of locations. On the freediver&#39;s back would be a primary choice, though chest or abdomen mounting, or even waist or hip mounting are possibilities. 
         [0055]    When the device is triggered, compressed air is released from the storage cylinder by the actuator portion and flows into the buoyancy portion of the device. If desired, the cylinder may be mounted at some distance from the buoyancy portion, and connected thereto by a hose or manifold. Such connecting portion may be fitted with quick disconnect fittings to permit ease of disassembly and maintenance. 
         [0056]    As an option, provisions can be made for the present invention to incorporate a device which automatically releases the weight belt upon inflation. Various types of release mechanisms could be incorporated into the design to effect this option. Releasable pins, latches, or buckles are all possibilities. 
         [0057]    One embodiment of the present invention provides a display which provides the freediver with information pertaining to their current dive and/or their diving profile. This display may be designed to be worn on the wrist like a watch, on the chest or waist, or even in the mask with a “heads-up” type display. Other varieties of monitoring display locations are possible and contemplated as within the scope of the present invention. 
         [0058]    Another embodiment of the present invention provides for a configuration that is specifically suited to serve as a useful safety device for apneists. Freedivers who are engaging in the pursuit of achieving maximum depths or durations, rather than hunting or photographing, have different needs from a safety apparatus. In the case of freedivers who seek to achieve a set maximum depth and return to the surface, the present invention may be configured to allow programming with the desired depth and the estimated time of that depth&#39;s attainment and subsequent return to the surface. The apparatus would be programmed to alert the user of a disruption of the expected depth/time curve, and provide emergency inflation. The apparatus could also observe a user&#39;s return to the surface and if progress toward the surface slowed or reversed, emergency inflation could be initiated. The implementation of such an embodiment would prove very beneficial and could greatly reduce the risks and costs associated with apnea training. 
         [0059]    In order to prevent difficulties resulting from multiple users diving together, and the risk of miscommunication among their safety apparatus, a system of serial numbers, multiple communication frequencies, and “handshaking” recognition protocols may be incorporated. Similarly, to provide for upgrades or replacement of individual components, the apparatus is able to perform a registration process, in order that a particular remote control unit may establish recognition with a particular actuator portion. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0060]    A better understanding of the present invention may be realized from a consideration of the following detailed description, taken in conjunction with the accompanying drawings, in which: 
           [0061]      FIG. 1  is a plan view of one particular arrangement in accordance with the invention; 
           [0062]      FIG. 2  is a rear quarter view of one particular arrangement in accordance with the invention, depicted on a human figure; 
           [0063]      FIG. 3  is a plan view of one particular arrangement of an inflation source and an actuator portion in accordance with the invention; 
           [0064]      FIG. 4  is a block diagram of one particular arrangement of an inflation source and actuator portion in accordance with the invention; 
           [0065]      FIG. 5  is a rear quarter view of one particular arrangement of an inflation source, actuator portion, buoyancy portion, and harness, in accordance with the invention, depicted in combination with a freediver&#39;s weight belt; 
           [0066]      FIG. 6  is a communications block diagram of one particular arrangement of an actuator portion in accordance with the present invention. 
           [0067]      FIG. 7  is a communications block diagram of one particular arrangement of a remotely locatable control unit in accordance with the present invention. 
           [0068]      FIG. 8  is a plan view of the display portion of remotely locatable control unit in accordance with the present invention. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       [0069]      FIG. 1  illustrates a freediving safety apparatus  10  having an inflation source  12 , an actuator portion  14 , here shown in cross-section, a buoyancy portion  16 , and a remotely located control unit (not shown). Flexible hose  18  connects buoyancy portion  16  and actuator portion  14 . Inflation source  12  has threaded connection means  20  for mounting to threaded receiving port  22  within actuator portion  14 . Redundant power supplies, in the form of batteries  24   a  and  24   b , are mounted within actuator portion  14 . Redundant solenoids  26   a  and  26   b  are mounted within actuator portion  14  and serve to effect the release of the compressed gas contents of inflation source  12 . Multiple pressure sensors  28   a ,  28   b ,  28   c , and  28   d , serve to detect and measure pressure in various chambers within actuator portion  14 . Transmitter  30  transmits sensor data, via radio frequencies, to control unit (not shown). Receiver  32  receives radio frequency signals from control unit. 
         [0070]    In use, buoyancy portion  16  would be worn about the neck and chest of a freediver, with actuator portion  14  and inflation source  12  mounted in a harness (not shown) and worn on the body, preferably the back. When a control unit detects conditions which required the inflation of the apparatus, for example, maximum depth exceeded, maximum time exceeded, manual deployment activated, or other preprogrammed conditions, then the control unit would signal the actuator unit  14  to activate the primary solenoid  26   a  to release the contents of inflation source  12  through passageways within actuator  14  and through connecting hose  18  to inflate buoyancy portion  16 . 
         [0071]    Through analysis of data reported by redundant sensors  28   a ,  28   b ,  28   c , and  28   d , in the different passageways within actuator portion  14 , and others (not shown), the remotely located control unit (not shown) monitors the status of the various components of the apparatus. If control unit detects that, despite commanding actuator portion  14  to inflate buoyancy portion  16 , no inflation has occurred, then control unit will command activation of secondary solenoid  26   b  within actuator portion  14  to release the contents of inflation source  12  into buoyancy portion  16 . 
         [0072]      FIG. 2  illustrates a rear quarter view of one embodiment of a freediving safety apparatus  10 , depicted being worn by a human figure. The inflation source  12 , actuator portion  14 , and buoyancy portion  16  are contained within the wearable garment  40 . Access panel  42 , formed in garment  40 , provides ready access to inflation source  12  and actuator portion  14 , for inspection and maintenance. Control unit  50  may be wrist-mounted (as shown) or otherwise remotely located, and communicates with actuator portion  14  using radio frequency or other method of communication, preferably wireless. 
         [0073]      FIG. 3  illustrates another embodiment of an inflation source  12  and an actuator portion  14  in accordance with the present invention. Inflation source  12  is connected to actuator portion  14 . Actuator portion  14  is equipped with a burst disk  60  or similar means for releasing pressure from the inflation source in the event of dangerous over-pressurization. Fill port  62  is provided to enable convenient refilling of the inflation source  12 . Fill port  62  may be adapted to provide convenient refilling of inflation source  12  through the use of common scuba tanks. 
         [0074]    Additional sensor means  28   e  provides data reflecting external pressure, i.e., depth. Redundant actuator controls  64   a  and  64   b  manage data and logic processing and memory storage means for monitoring and operation of actuator functions. Redundant actuator controls  64   a  and  64   b  are capable of receiving programming and data transfer and other communications with remote control unit  50 , through use of transmitter means  30 . Such communications are preferably wireless. 
         [0075]    Redundant function capability is preferably incorporated into the design of the present invention, through the implementation of redundant power sources  24   a  and  24   b , which are preferably conveniently replaceable batteries. Redundancy may be provided throughout the actuator unit  14 , including: high pressure sensors  28   a  and  28   b  for sensing pressure level of inflation source  12 , low pressure sensors  28   c  and  28   d  for sensing and detecting effective release of contents of inflation source  12 , valves  26   a  and  26   b  for controlling the release of pressurized contents of inflation source  12 . 
         [0076]    Inflation source  12  connects to actuator portion  14  through threaded portion  20  on inflation source  12 , which attaches to threaded receptacle  22  formed in actuator portion  14 . 
         [0077]      FIG. 4  illustrates the relation of various components to another embodiment of actuator portion  14 . Redundant power sources  24   a  and  24   b  provide electrical energy required to operate actuator unit  14 . Along with other redundant components, including redundant controls  64   a  and  64   b , redundant valves  26   a  and  26   b , redundant high pressure sensors  28   a  and  28   b , redundant low pressure sensors  28   c  and  28   d , the actuator portion  14  provides a level of performance redundancy by isolating each redundant system from the other. Even if one system fails, the other redundant system will allow actuator portion  14  function as anticipated. 
         [0078]    In order to enable a user to disable the apparatus at the end of a current dive, and prepare it for a subsequent dive, a deactivation sensor  68  is provided to signal actuator controls  64   a  and  64   b . Deactivation sensor  68  operates in concert with disable trigger  104  (not shown) incorporated in remotely locatable control unit  50 . Upon resurfacing following a dive a user is required to bring the disable trigger  104  in close proximity to deactivation sensor  68 , in order to signal that the user is conscious and operational at the end of the dive. Other mechanical or electrical Signaling or switching means may be used if desired. The magnetic deactivation sensor  68  of the present invention is beneficial in that it allows a user to locate or mount the deactivation sensor  68  in a location of their choosing. The control unit  50  will communicate the activation of disable trigger  104  to actuator portion  14  in order to effect a reset of the apparatus. 
         [0079]    If a user reaches the surface following a dive and is able to disable the apparatus using the disable trigger  104  and deactivation sensor  68 , it is still possible for that user to blackout. The logic programmed in the apparatus may be configured to initiate emergency inflation if a user submerges below a predetermined depth within a relatively brief period after reaching the surface. In the unusual event of a situation requiring a user to immediately dive again upon reaching the surface, e.g. a boat bearing down on them, a selecting of certain buttons on control unit  50  (not shown) may provide for a temporary override of this feature. 
         [0080]      FIG. 5  illustrates a basic apparatus in accordance with the present invention. Inflation source  12 , attached to actuator portion  14 , is affixed to harness  52  which is then partially or completely covered by garment  40 . Access panel  42  (not shown) may be provided to enable inspection, removal, or refilling of actuator portion  14  or other components. Access panel  42  may be configured as a compartment, pocket, or sleeve feature of garment  40  or harness  52 . 
         [0081]    Buoyancy portion  16  is retained by harness  52  or garment  40  to reduce drag while swimming. Secure linkage or attachment of buoyancy portion  16  to harness  52  may be provided by straps, clips or other means. Garment  40  permits buoyancy portion  16  during inflation, through expansion or release. Connection hose  18  allows released air from actuator portion  14  to pass into buoyancy portion  16  to cause inflation. Connection hose  18  may incorporate quick disconnect fittings and utilize flexible materials to facilitate maintenance and component placement. Alternately, actuator portion  14  may provide direct connection to buoyancy portion  16 , thereby allowing direct passage of gas from inflation source  12 . 
         [0082]    An automatic release mechanism may be incorporated into the apparatus, preferably into harness  52 , to enable the actuator portion  14  to automatically ditch the user&#39;s weight belt in emergency inflation conditions. 
         [0083]      FIG. 6  depicts a block diagram flow chart of information and data communication of an actuator portion  14  in accordance with the present invention. Control processors  64   a  and  64   b  receive data of inflation source  12  pressure from high pressure sensors  28   a  and  28   b , data of buoyancy portion  16  pressure from low pressure sensors  28   c  and  28   d , and relative depth information from external pressure sensor  28   e . Batteries  24   a  and  24   b  provide necessary electrical power for the system. Diagnostic communications controller  78  enables programming and communication with actuator portion  14 . Controller  78  is preferably a convenient computer connection or port, such as USB, but may be wireless, e.g., bluetooth. The manufacturer, dealer, service center, or a user may utilize diagnostic communications controller  78  for additional programming of the apparatus for system updates; provide for initial configuration and set up; allow customization through additional optional features or functions of the apparatus which may be provided; allow diagnostic information to be retrieved; provide detailed reports of stored data to be downloaded and viewed or charted using a computer. 
         [0084]    Control processors  64   a  and  64   b  monitor data from sensors and perform comparisons to predetermined values selected by a user. Logic commands programmed and stored in control processors  64   a  and  64   b  allow recognition of circumstances requiring emergency inflation, and initiate activation of inflation valve  26   a . If sensors do not reflect the successful opening of valve  26   a  and subsequent release of compressed gas from inflation source  12 , processors  64   a  and  64   b  initiate activation of valve  26   b . Communication with control unit  50  is provided by transmitter communication controller  30 , which establishes communications transmission with receiver  32 . 
         [0085]      FIG. 7  depicts a block diagram flow chart of information and data communication of a control unit  50  in accordance with the present invention. Control unit  50  is remotely mountable by a user, and is preferably worn “watch style” on the wrist or arm of a user. Control processor  164  receives data of external or water temperature from sensor  129 ; data of external pressure or depth from sensor  128 ; and communicates with communication controller  30  of actuator unit  14  by communication controller  130 . 
         [0086]    A display  102 , preferably LCD alphanumeric, provides a means for control unit  50  to provide a user with information (current or historical), allows interaction with the control unit  50 , and also may be used to alert a user through visual signals. Control unit  50  allows a user to select, or enter, values for configuring the apparatus and programming the values that will be used to determine the occurrence of emergency conditions requiring inflation. This may be achieved through buttons  140 , or other means that enable a user to enter data or select values related to the operation or configuration of the apparatus. A battery  124  provides power for the operation of control unit  50 . Control unit  50  also provides a means for disabling the actuator device  14 . Preferably, this is achieved by a magnetic disable trigger  104  provided by control unit  50 . 
         [0087]      FIG. 8  depicts a top plan view of control unit  50 , showing sample characters represented upon display  102 . Such a display  102  is preferably an LCD device, providing excellent resolution and pixel selection. Exemplary data values that might be displayed could include a user&#39;s preselected depth value and time value for triggering inflation; time elapsed during a current dive—which could change to display a counting down of time to inflation as the “trigger” time approaches; current or maximum dive depth—which could change to display counting down of depth to inflation as the “trigger” depth approaches; water or ambient temperature. Pressure sensor  128  provides data related to depth values, while temperature sensor  129  provides for temperature readings on display  102 . Data values for depth, temperature and time are recorded at predetermined intervals and stored for subsequent retrieval by a user or others. Sufficient memory is provided to enable storage of data sampled each second of a dive, for several days of diving. After passage of a predetermined period of time, for example 15 minutes, following returning to the surface, control unit  50  directs display  102  to revert to displaying usual watch values. Time of day, day of month, month and year, along with other desirable values may be displayed. 
         [0088]    Although there have been described hereinabove various specific arrangements of a FREEDIVING SAFETY APPARATUS in accordance with the invention for the purpose of illustrating the manner in which the invention may be used to advantage, it will be appreciated that the invention is not limited thereto. Accordingly, any and all modifications, variations or equivalent arrangements which may occur to those skilled in the art should be considered to be within the scope of the invention as defined in the annexed claims.