Consistent unbiased automated method for evaluating and examining student pilots

Abstract

A system and method of evaluating and examining a student pilot in an automated, consistent, unbiased way using a flight data recorder and analyzing the flight data recorded in real time.

Claims

1. A consistent unbiased automated method for evaluating and examining a student pilot comprising: a. a flight data recording device affixed to an aircraft collecting flight data; b. a software program running on a computer processor accessing the flight data recorded by the flight data recording device; c. wherein the software program running on the computer processor calculates the difference between proposed flight data provided prior to the beginning of a maneuver and actual flight data recorded while the maneuver was conducted and calculates a score based on the difference between the proposed data and the actual data.

2. A consistent unbiased automated method for evaluating and examining a student pilot of claim 1 wherein the computer processor is located inside the flight data recording device.

3. A consistent unbiased automated method for evaluating and examining a student pilot of claim 1 wherein the computer processor is located outside the flight data recording device.

4. A consistent unbiased automated method for evaluating and examining a student pilot of claim 1 wherein the software program running on the computer processor determines whether the student pilot has passed or failed the maneuver based on the calculated score.

5. A consistent unbiased automated method for evaluating and examining a student pilot of claim 1 wherein the proposed flight data describes one maneuver.

6. A consistent unbiased automated method for evaluating and examining a student pilot of claim 1 wherein the proposed flight data describes more than one maneuver.

7. A consistent unbiased automated method for evaluating and examining a student pilot of claim 1 wherein the flight data recording device is a Garmin G-1000.

8. A consistent unbiased automated method for evaluating and examining a student pilot of claim 1 wherein the flight data recording device is a Wingbug.

Description

DRAWINGS

(1) FIG. 1 shows an example of a steep 90° left turn with a differential in heading and no differentials in altitude, airspeed, or initial and terminal bank.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(2) Referring now to FIG. 1, a steep 90° left turn with a differential in heading and no differentials in altitude, airspeed, or initial and terminal bank is illustrated as an example of the system and method. At 100 and at time zero, the student and the instructor begin the maneuver. The tested protocol for a steep 90° turn to the left is that the turn is initiated and at some time T later the turn is completed. The flight data recording system installed in or on the aircraft notes the direction of flight is 0° at the initiation of the maneuver. At 101 and time T the maneuver is concluded. Next, the flight data recording system installed in or on the aircraft notes the direction of flight at 80°. Next, the computer calculates the difference between the attitude (direction) of the aircraft at the beginning of the maneuver and the attitude (direction) of the aircraft at the end of the maneuver (0°−80°=−80°). Next, the computer takes the absolute value of the calculated value. Next, the computer consults the FAA assigned value for demonstrating the ability to make a steep, 90° planar turn to the left. Assuming the value is 90°, the recorded absolute value of 80° presents a 10° differential. The score for the maneuver is calculated based on the differential.

(3) The maneuver may be simple as above, or it may be complex with multiple monitored parameters in multiple axes. For example, a steep 90° planar turn with differentials allowed in altitude of ±100 feet, airspeed of ±10 knots, bank of ±5°, and roll out from the entry heading of ±10°.

(4) Each category (altitude, airspeed, bank angle, and heading angle) will have an associated error amount and an error threshold. In one embodiment, a perfect maneuver would result in 0 error score. The most extreme passing flight would result in a 100.

(5) Each category accounts for 1/# categories of the maximum error. The percentage of error in that category is multiplied by that category's maximum error amount and added to the overall total error. For example, a student completing this maneuver that had differentials of +10 feet, −5 knots, +1° bank angle, and +5° heading angle would have a score of:
score=((+10 feet/+−100 feet)×25)+((−5 knots/+−10 knots)×25)+((+1° bank angle/+−5° bank angle)×25)+((+5° heading angle/+−10° heading angle)×25)  [eq. 1]
Or:
score=2.5+12.5+5.0+12.5=32.5  [eq. 2]

(6) Categories may be weighted as necessary. Error amounts can be shifted as necessary (i.e. the error associated with a differential between +70 and +80 feet being weighted as greater than the error associated with a differential ranging from +0 to +10 feet).

(7) The data is collected and graded in real time against a previously articulated FAA scoring criteria. Of course, the instructor would start and stop the grading at the beginning and end of each maneuver. The score would be captured and stored for later review.

(8) Minimum overall passing score criteria (e.g. 80% overall with no single maneuver less than 70%) may be established within FAA guidelines.

(9) Other embodiments of the invention are included by reference. For example, it would be obvious that measurements can be taken at all points in time during the maneuver. The data is again collected and graded in real time against a previously articulated FAA scoring criteria. In this case, the instructor would start and stop the data collection at the beginning and end of each maneuver. The processor itself would analyze the data at various points in time as the maneuver was completed and grade against a previously articulated FAA scoring criteria.

(10) It will be obvious to one having skill in the art that an automated version of the present invention may be constructed that does not require an instructor. For example, a flight manifest, or route, may be constructed beforehand. The manifest, or route, contains an arbitrary number of turns, elevations, speeds, and elapsed times. This route is provided to the pilot and to the present invention. As the pilot travels along the manifest, or route, the present invention collects information regarding: 1) The angle and speed of turns; 2) The horizontal location, angle of climb of dive, and beginning and ending elevation; 3) The speed; and, 4) The time at which the maneuver was performed or the location was reached. The present invention compares this collected information with the manifest, or route, provided before the flight was conducted. The differentials associated with each element of the flight are then calculated and summed into a score. The score would then be available for use by the pilot's superiors for analysis and use in flight performance grading and analysis.