Abstract: An apparatus for inflating an air bag of a protection device. The apparatus includes a canister including a first compartment and a second compartment. The first compartment is adapted to contain a compressed gas. A seal is between the first compartment and the second compartment which is adapted to seal the compressed gas inside the first compartment. The second compartment includes a two-step mechanism configured to break the seal to cause thereby an initial gas flow from the first compartment into the second compartment. The initial gas flow causes a wide opening in place of the seal to be created for rapid gas flow through the second compartment and into the air bag to rapidly expand the air bag.

Abstract: Detection of a fall of a user wearing the device. A processor is configured to time sample and to input multiple values over time of: the acceleration vector, the angular velocity and the point-to-point distance. The processor is configured to determine over time the direction of gravity from the acceleration vector. The processor is configured to integrate over time the angular velocity to produce an orientation angle of the protection device relative to the direction of gravity. The processor, responsive to the point-to-point distance and the orientational angle, is configured to determine heights over time of the distance sensor from the ground. The processor is configured to indicate initiation of a potential fall event by a change in downward acceleration measured by the accelerometer or a rapid decrease in the determined heights of the distance sensor from the ground.

Abstract: A hip protector system includes an inflatable airbag, a proximity sensor to measure a distance to a point on the ground surface, a gyro to provide spatial orientation of the waist plane of the user, an accelerometer to determine the vertical acceleration of the waist plane of the user and a micro-controller unit. The micro-controller unit calculates a height based on proximity measurement and spatial orientation, computes values of downward velocity based on a change of the height in time and based on the vertical acceleration integrated over time and correlates the downward velocities to validate a true height in time to the ground surface. The airbag is inflated to protect the user responsive to the true height.

Abstract: An active hip protector system and method for hip fracture prevention are introduced in order to overcome the shortcomings of existing methods of preventing hip fractures; namely: to provide effective impact protection and eliminate false fall alarms. The hip protector system comprises a belt-like pouch, worn over the user's waist, containing airbags which are inflated to a large size ensuring that the user's thighs will not hit the ground upon impact, once the system detects a fall. The pouch contains all of the necessary elements for fall detection and activating inflation of the airbags. Incorporation of distance measurement sensors and cross reference with acceleration and spatial orientation sensors enable reliable detection of impending collision with the ground. The pneumatic system, including the airbags, is carried within the pouch or, alternatively, can be placed in a location that is prone to falling.