In my previous reply, I explained the timeline and nature of the HSCA acoustical analysis. However, I purposely did not go into much detail on the grassy knoll shot, because that would have made the reply about 50% longer, and it was already long enough. When you understand how Weiss and Aschkenasy (WA) confirmed the grassy knoll shot, you more fully understand the powerful nature of the acoustical evidence.
* The grassy knoll shot is the 145.15 shot, the third of the four shots that the HSCA acknowledged on the dictabelt recording. The BBN scientists noted that this was shot was aimed at JFK when the limousine was “near the limousine position seen in frame 313” (8 HSCA 6).
* The main reason that WA were asked to review the BBN analysis was that BBN said the grassy knoll shot had a certainty factor of only 50%. Everyone recognized that if the 145.15 shot was confirmed to be a shot from the grassy knoll, this would automatically prove that more than one gunman fired at JFK, since no one doubted that at least one shot was fired from behind, and since the sixth-floor gunman could not have fired a shot from the grassy knoll.
BBN said the three other shots had much higher certainty factors:
1st shot: 88% (based on three matches)
2nd shot: 88% (based on three matches)
4th shot: 75% (based on two matches)
* The third shot had a 50% certainty factor because it matched one test-firing shot from the grassy knoll but matched two test-firing shots from the TSBD. The grassy knoll match had a correlation coefficient of 0.8, a very high coefficient, whereas the two TSBD matches had a correlation coefficient of 0.7. Only five other matches of the 15 matches (really correlations) had a coefficient of 0.8. Based on this fact and on other factors, the BBN scientists concluded that the third shot came from the grassy knoll, but they knew that a more-refined analysis was needed to confirm this and to prove that the two TSBD matches were false matches.
The BBN scientists knew that the locations of the microphones in the test-firing caused false alarms/false matches:
They suspected that if they had used more microphones so that the microphones had been closer to each othe3r, the two TSBD matches on the third shot would not have occurred.
* WA realized that the problem was that the microphones in the test firing were spaced 18 feet apart. The 18-foot spacing was the reason that BBN applied a 6-millisecond acceptance window when determining matches.
* As WA explained in their testimony, they did not need to do another test firing in Dealey Plaza to solve the microphone-spacing problem. They knew they could do a computerized sonar analysis that would duplicate the conditions of closer microphone spacing and the resulting echo patterns. They wrote a sonar analysis program that simulated an echo pattern for 180 locations surrounding the location of the test microphone that gave the best match for the third dictabelt impulse pattern, i.e., the grassy knoll shot.
WA had written similar sonar analysis programs for the U.S. Navy—that was one of the reasons the Acoustical Society of America recommended them to the HSCA.
Significantly, the sonar analysis enabled WA to reduce the acceptance window for a match from 6 milliseconds down to 1 millisecond, a 500% narrower window, which vastly reduced the possibility of a false match. WA also applied a noise threshold to further distinguish between non-gunfire noise and gunfire impulses.
* When WA conducted the solar analysis, they found that the dictabelt grassy knoll shot was a practically perfect match for a simulated test-firing shot at a position 5 feet from the microphone position.
In the first sonar analysis comparison, done without the noise threshold, WA found that when the muzzle blast of the test shot was aligned with the first large impulse of the 145.15 shot—the grassy knoll shot—all 26 echoes of the test shot occurred within 1 millisecond of corresponding impulse of the 145.15 shot, an impressive correlation.
In the second sonar analysis comparison, WA found that when they applied the noise threshold, the grassy knoll shot had 14 large impulses compared to the 12 large impulses of the test-shot pattern. Crucially, 10 of the 12 impulses in the test shot matched impulses in the grassy knoll shot to within 1 millisecond. This is an astounding correlation. Dr. Weiss explained:
* Dr. Barger explained the importance of the WA analysis:
* Actually, due to the fact that the two groups of HSCA acoustical experts worked separately, a math error arose in the calculation of the odds relating to the grassy knoll shot. The probability that the grassy knoll shot was the result of random noise was computed to be less than 5%, or less than 1 in 20, based mainly on a miscalculation of the value of p in the formula. The odds are even lower than WA calculated. Dr. Donald Thomas has demonstrated that they are actually only 1 in 100,000, or 100,000 to 1 against (http://jfklancer.com/pdf/Thomas.pdf). To put it another way, there is a 99.999% chance that the grassy knoll shot is a gunshot.
* Revealingly, the NRC panel recognized that WA had assigned the wrong value for p in their calculations; however, the panel not only failed to tell their readers that WA had overestimated the odds that the grassy knoll shot was random noise, but they used erroneous assumptions in their own calculations to make it seem like there was a 22% chance that the grassy knoll shot was random noise.
Yes, in so doing, the NRC panel was admitting there was a 78% chance that the grassy knoll shot was a gunshot, but 78% is quite a bit lower than 95%+ (and far lower than 99.999%).
First of all, it sounds like Weiss and Aschkenasy (W&A) may have compared a lot of locations with 145.15 in the vicinity of the microphone 3 ( 4 ). Perhaps starting 15 feet up the street toward Houston, in a line of 10 feet across. And checked every foot as they went down Elm Street, until they got passed microphone 3 ( 4 ) by 15 feet. So, they might have checked, by computer, a grid of 31 by 11 locations or 341 locations. If there was that many, it might be a mathematical certainty that they would find an excellent correlation, with a hypothetical microphone location. One might not find an excellent correlation with the first of the 341 hypothetical microphone locations, or with the second, but it there might be a high chance one will found before one is done with all 341 hypothetical locations.
I have no idea the size of this array, but for the rest of this post, I will refer to it as the “31 x 11” array, to make it clear what array I am talking about.
Weiss and Aschkenasy (W&A) found a great correlation with the 1963 impulse at 145.15 and one of the Grassy Knoll test shots of 1978.
There were 12 test shots that were compared. 4 of them from the grassy knoll:
Test Shot 5: Rifle, fired at Target 2 (near z224)
Test Shot 8: Rifle, fired at Target 3 (near z313)
Test Shot 12: Rifle, fired at Target 4 (near Mt. Tague)
Test Shot 9: Pistol, fired at Target 3 (near z313)
W&A believe they can predict what the waveform, recorded by 3 ( 4 ) would look like from a certain location five feet away. Did they confirm that?
This can be done with running the calculations for a location where microphone 3 ( 3 ) was. And then comparing the calculated waveform with the real waveform that was recorded at 3 ( 3 ) with the same shot.
Question 1:
Did they confirm that their mathematical model would predict a waveform at 3 ( 1 ), 3 ( 2 ), 3 ( 3 ), 3 ( 5 ), 3 ( 6 ), 3 ( 7 )
by comparing
• A mathematical calculation of what a Grassy Knoll shot fired at Target 3 would look like at these six locations?
with:
• The real Grassy Knoll test shot fired at Target 3, recorded at those locations? If their predictions, based on:
• The waveform recorded in 1978 for microphone 3 ( 4 )
• Running the calculations for the locations of 3 ( 1 ), 3 ( 2 ), 3 ( 3 ), 3 ( 5 ), 3 ( 6 ) and 3 ( 7 )
Do not match the recorded 1978 waveforms for what 3 ( 1 ), 3 ( 2 ), 3 ( 3 ), 3 ( 5 ), 3 ( 6 ) and 3 ( 7 ) actually recorded in 1978,
then one cannot put much confidence in the calculations for that spot that was 5 feet from 3 ( 4 ).
Question 2:
Which of these 4 test shots did W&A find the strong correlation with 145.15? Was it 5, 8, 12 or 9?
Question 3:
Did they make as an in-depth search, not just for one of the test shots but of all 4 Grassy Knoll test shots, to find every “Grassy Knoll” correlation they could, over this “31 x 11” array?
Question 4:
Did the make a really in-depth search, of all 12 test shots, to find every correlation they could over this “31 x 11” array? It is important for to search for correlations, even if they are “impossible”, because they would contradict each other.
If one conducts the same procedure with all 12 test shots:
• and find no strong correlations, except for Test Shot # 8, at a spot 5 feet from 3 ( 4 ),
that is good.
• But finds a strong correlation for Test Shot # 8, at a spot 5 feet from 3 ( 4 ),
and finds a strong correlation for Test Shot # 3, at a spot 7 feet from 3 ( 4 ),
and finds a strong correlation for Test Shot # 11, at a spot 2 feet from 3 ( 4 ),
that is bad.
Finding correlations for shots fired from different positions at different targets strongly implies that one is just finding random correlations.
I should note, is that the best thing about the BBN tests, and compiling Exhibit F-367, is that they didn’t limit themselves to only the results that were possible. They could have searched for a correlation near 2 ( 5 ) and as soon as they find one, stop there. But they didn’t, they still searched for other correlations, and found correlations near 2 ( 5 ) for:
• A shot from the TSBD fired at Target 1 (near z155)
• A shot from the TSBD fired at Target 3 (near z313)
• A shot from the Grassy Knoll at Target 4 (Mr. Tague)
If they stopped after finding the first correlation, the data would have looked good. But by being more through, and checking all the other possibilities, they thoroughly test their procedure. Which was found suspect by the multiple and conflicting correlations. But it was good they checked for other “impossible” correlations.
I am concerned that W&A might not have done something similar. * Actually, due to the fact that the two groups of HSCA acoustical experts worked separately, a math error arose in the calculation of the odds relating to the grassy knoll shot. The probability that the grassy knoll shot was the result of random noise was computed to be less than 5%, or less than 1 in 20, based mainly on a miscalculation of the value of p in the formula. The odds are even lower than WA calculated. Dr. Donald Thomas has demonstrated that they are actually only 1 in 100,000, or 100,000 to 1 against (http://jfklancer.com/pdf/Thomas.pdf). To put it another way, there is a 99.999% chance that the grassy knoll shot is a gunshot.
I must confess that I am a little skeptical that Barger, Weiss and Aschkenasy could have been so far off with their math. Instead of a 1 in 20 chance that the correlations could have been from chance, the odds were actually 1 in 100,000? Math errors of this magnitude are pretty rare for people who are good at math.
Question 5:
Do Dr. Barger, Dr. Weiss and Mr. Aschkenasy all agree with Dr. Thomas on this? And it does not look good how much these calculations of the odds of these correlations being a result of just chance has changed wildly over the years. It has gone
• from 1 in 2 (BBN)
• to 1 in 20 (W&A)
• to 1 in 25 (Dr. Thomas correcting W&A)
• to 1 in 100,000 (Dr. Thomas correcting BBN, W&A and himself)