Controlled energy absorption of seats for impact

What is claimed is: 1 . A method comprising: determining a weight of an occupant of a seat of an aircraft; calculating, using a processor, a stroke load of a seat energy absorber operatively coupled to the seat based on the weight of the occupant; and setting the seat energy absorber to the calculated stroke load. 2 . The method as defined in claim 1 , further including determining an available stroke of the seat, and wherein calculating the stroke load is further based on the available stroke. 3 . The method as defined in claim 2 , wherein the available stroke is determined based on an optical sensor. 4 . The method as defined in claim 1 , wherein the stroke load is further based on conditions of an impact. 5 . The method as defined in claim 1 , the seat energy absorber is set to the calculated stroke load prior to takeoff of the aircraft. 6 . The method as defined in claim 1 , further including re-calculating the stroke load based on impact conditions of a predicted impact. 7 . The method as defined in claim 6 , wherein re-calculating the stroke load is further based on one or more of: terrain topography; velocity of the aircraft; acceleration of the aircraft; altitude of the aircraft; weight of the aircraft; and calculated impact characteristics. 8 . The method as defined in claim 1 , wherein the weight is determined by a load cell when the aircraft is on the ground. 9 . An apparatus comprising: a weight sensor on a seat of an aircraft; a seat energy absorber operatively coupled to the seat; an actuator operatively coupled to the seat energy absorber; and a processor communicatively coupled to the actuator, the processor to calculate a stroke load of the seat energy absorber based on occupant weight data from the weight sensor, wherein the actuator is to adjust the seat energy absorber based on the calculated stroke load. 10 . The apparatus as defined in claim 9 , further including a position sensor to determine a relative position of a seat bucket of the seat to a frame of the seat, wherein the processor calculates the stroke load further based on the relative position. 11 . The apparatus as defined in claim 10 , wherein the position sensor includes an optical sensor. 12 . The apparatus as defined in claim 9 , wherein the actuator includes a rotational motor. 13 . The apparatus as defined in claim 9 , wherein the stroke load is re-calculated based on data received from a flight interface, the data associated with an imminent impact. 14 . The apparatus as defined in claim 13 , wherein the data associated with the imminent impact includes one or more of: predicted impact conditions; terrain topography; velocity of the aircraft; acceleration of the aircraft; altitude of the aircraft; weight of the aircraft; and calculated impact characteristics. 15 . The apparatus as defined in claim 9 , wherein the weight sensor includes a load cell operatively coupled to the seat energy absorber. 16 . A tangible machine readable medium having instructions stored thereon, which when executed, cause a processor of a seat controller of an aircraft seat to: receive a weight of an occupant from a weight sensor of the seat; and calculate a stroke load of an energy absorber operatively coupled to the seat based on the received weight. 17 . The machine readable medium having instructions stored thereon as defined in claim 16 , which when executed, further cause the processor to receive a relative position of a bucket of the seat from a position sensor mounted to the seat, wherein the stroke load is calculated further based on the relative position of the bucket. 18 . The machine readable medium having instructions stored thereon as defined in claim 16 , which when executed, further cause the processor to set the energy absorber to the calculated stroke load. 19 . The machine readable medium having instructions stored thereon as defined in claim 18 , which when executed, further cause the processor to re-calculate the stroke load based on predicted impact conditions. 20 . The machine readable medium having instructions stored thereon as defined in claim 19 , wherein the predicted impact conditions include one or more of: terrain topography; velocity of the aircraft; acceleration of the aircraft; altitude of the aircraft; weight of the aircraft; and calculated impact characteristics.