|Title:||United States light sport aircraft accidents resulting in fatalities and/or serious injuries by type of incident in percentages for the period 2005 to 2011|
Start of full article - but without data
Light Sport Aircraft Accidents, 2005-2011
Fatal And/Or Serious Injuries
Stall/spin (XX.X%) Loss of control (XX.X%) Engine failure (XX.X%) Mechanical (XX.X%) Miscellaneous/other (XX.X%)
Note: Table made from pie chart.
The aviation world rejoiced in the summer of 2004 when the FAA announced the long-awaited adoption of its light sport aircraft (LSA) rulemaking, and the sport pilot certificate. Small, simple aircraft manufactured to industry consensus standards instead of the agency's regulations should he vastly less expensive than traditional entry-level aircraft. Pilots who self-certify medical fitness to fly on the basis of their state's driver license requirements could avoid the expense of an FAA medical certificate (the same pilot self-certification of medical fitness to fly applying to private and higher pilots still applies to sport pilots). Overall, the price barrier to personal aviation should fall away, causing a resurgence in new pilot starts and a renaissance in recreational and entry-level career track flying.
Whether the sport pilot certificate and LSAs have achieved that goal any better than the very similar recreational pilot certificate and airplane category fifteen years before is more appropriately addressed in something other than Aviation Safety magazine. In short, however, the intended target for sport pilot and LSAs (a new generation of young pilots to revitalize general aviation) seems to have been replaced instead with older pilots nearing the end of their flying career, stepping down to LSAs from traditional ones.
That being the case, at least one thing should be certain--since these new pilots have experience in more capable airplanes, the accident record in LSAs should be very good, and better than traditional training airplanes attracting newer pilots. After all, we know that training and experience in heavier, more complex airplanes makes you safe to fly lighter, less complex types, right? Not so fast there, folks. It turns out the light sport safety record doesn't reflect this fallacious bit of aviation conventional wisdom.
FOR THE RECORD
To learn about the light sport safety record and compare it to traditional light airplanes, I searched NTSB final reports for the years 2005 through the end of 2011--basically the light sport era to date. For purposes of this comparison, I discarded weight-shift machines, LSA balloons and gliders, focusing on the traditionally-controlled, i.e., control stick or yoke, and wing-and tail-mounted control surface aircraft. (The FAA does not consider LSAs to be "airplanes" because they do not meet a Federal standard for that category. Instead, LSAs are aircraft.)
The rules permit operating some FAA-certificated airplanes by a sport pilot. These so-called "legacy" LSAs--some models of Piper Cubs, Aeronca Champs, Taylorcraft and Ercoupes, but not all--may be operated by a sport pilot if the airplane has never been certified to a maximum gross weight greater than XXXX pounds, the non-amphibious LSA upper limit. In my review of NTSB reports, I discarded cases where a sport pilot was illegally operating an airplane not meeting the LSA restrictions.
The result was a record of XXX reports in the study period involving LSAs that were severe enough to warrant an NTSB investigation (serious or fatal injury and/or substantial damage or the aircraft destroyed). Of those XXX reports:
* Forty-three events, or XX.X percent of the total, caused serious injury or death (the difference between serious injury and death in an aircraft accident is largely a matter of circumstances ... and luck).
* One hundred reports, XX.X percent of the total, caused substantial aircraft damage or destroyed the aircraft (not surprising, since this is a threshold criterion for NTSB reporting. Mishaps that seriously injury or kill an occupant extremely rarely cause only minor aircraft damage).
On to the meat of our investigation: what actually causes LSAs to crash, and what might we do about it?
The NTSB-identified probable cause for reported LSA accidents breaks down thusly:
Loss of control (LOC): Loss of aircraft control is by far the largest single cause of LSA accidents. Some XX.X percent of all NTSB-reported LSA mishaps result from the pilot's loss of control of the aircraft. Perhaps as expected, the greatest number of LOC events occur on landing, usually with a crosswind--XX.X percent of all such accidents. Losing control on takeoff accounts for X.X percent of the total, while a very small percentage (X.X percent and X.X percent, respectively) are attributed to LOC in maneuvering flight and attempted VFR into IMC (the one VFR-into-IMC event with an LSA took place at night, a sport pilot no-no).
Significantly (at least I think so), X.X percent of all LSA crashes occurred when the pilot lost control after a canopy came open in flight, usually during or right after takeoff. I counted these as a separate category of LOC, included in the XX.X percent total but not any of the other LOC categories. In only one case did the NTSB cite manufacturer's statements that drag from the open canopy would seriously impair aircraft performance. Instead, these events cite pilot distraction as the proximate cause after an LSA's canopy came open in flight ... and blame lack of pilot familiarity with the latching mechanism as the main instigator. Just think: a XX-second briefing on how to properly secure and check the cockpit canopy could eliminate nearly one-tenth of all LSA accidents!
Stalls and spins: Aerodynamic stalls that sometimes develop into spins are cited in XX.X percent of all LSA mishaps studied. We usually think of stalls in the turn from base to final as the most common scenario, but at least in light sport aircraft, more stalls occur on takeoff (X.X percent of all reports) than on landing (X.X percent). Moreover, the same number of stalls occurred during maneuvering flight away from the traffic pattern as did in the landing circuit.
Stall and spin awareness is an area of emphasis in the recent update of the FAA's private pilot practical test standards. It appears there's good reason even for experienced pilots stepping "down" to LSAs to refresh their knowledge of angle of attack, stall avoidance and recognition.
Mechanical failure: Identified, non-engine, pre-impact mechanical failure is just behind stalls in terms of LSA accident frequency, noted in XX.X percent of all NTSB reports. The specific in-flight failures cited are:
* Failure of preexisting cracks in the nose gear fork, not addressed in a recent inspection.
* Flight-control system failure: bent/broken control pushrods or cables.
* Failure of landing gear bolts.
* Engine oil line failure (improper maintenance).
* Overstress and failure of a main wheel.
* Propeller gearbox failure leading to propeller separation in flight, which cut off the aircraft's tail resulting in loss of control.
* Electrical fire due to fuse failure.
* Failure of ballistic parachute to separate after activation during preproduction flight tests.
* Failure of ballistic parachute to deploy when activated during preproduction spin testing, resulting in the pilot bailing out with a personal parachute.
* Fuel siphoning due to the improper design of the fuel filler port, resulting in fuel exhaustion in flight.
* In-flight separation of the wing.
* In-flight structural failure of the horizontal stabilizer leading to stresses that caused wing separation.
* Trim system failure resulting in loss of control on takeoff.
* Landing gear strut failure.
* Bending of engine throttle control mechanism, resulting in partial power loss.
Engine failure: Engine failure not resulting from known fuel management issues on the part of the pilot is next, comprising XX.X percent of the NTSB record of light sport probable causes. Add the fuel management events (X.X percent of the total), as is usually the case in reported engine failures, and the total engine failure rate is XX.X percent. Put the non-fuel-management engine failure reports together with other mechanical failures and mechanical failures represent XX.X percent of all LSA events in the NTSB database.
Hard landing, landing short: Technique-related crashes in the landing phase not identified as involving stalls resulted in X.X percent of LSA accidents events, weighted heavily toward hard landings.
Miscellaneous: The remaining NTSB events were the result of:
* Collision with object immediately after takeoff;
* Collision with objects on the ground;
* Controlled Flight into Terrain (CFIT).
If we look only at those NTSB reports involving an LSA and serious injury or death, this is how the probable causes break down:
Stalls and spins: Some XX.X percent of the total resulted from stalls and spins. Of the total ...
* XX.X percent of all fatal LSA crashes were a stall on initial climb following takeoff.