NavList:
A Community Devoted to the Preservation and Practice of Celestial Navigation and Other Methods of Traditional Wayfinding
Re: Calculate GHA Aries in your head
From: Gary LaPook
Date: 2021 Mar 1, 15:46 -0800
From: Gary LaPook
Date: 2021 Mar 1, 15:46 -0800
I had posted this in 2008:
"Re: 3-Star Fix - "Canned Survival Problem"
From: Gary LaPook
Date: 2008 Jun 14, 03:44 -0400
Being the conscientious navigator that I am, I followed my usual practice of memorizing some data from the 2008 Nautical Almanac so that I would have it available for emergency use.
The first thing I memorized was the GHA of Aires at 0000 Z January 1, 2008 which is 100º 01.9' and also remembering that Aires advances 59.139' each day. With this information you can calculate GHA Aires for 0000 Z on June 9, 2008 which is the 161st day of the year but is only 160 days from January 1st. So multiplying 59.139' times 160 days gives 157º 42.2' to which you add the starting value of 100º 01.9' to come up with the GHA Aires on June 9th at 0000 Z of 257º 44.1'. To this you add the change of GHA for the time since 0000 Z (3 hours 42 minutes 10 seconds for the Vega shot) by multiplying the time interval by the rate of change of 15.041º per hour making 55º 41.6' making the GHA Aires at the time of the Vega shot of 313 º 25.7'.
I also memorized the SHAs and the Declinations of ten of the navigation stars ( nobody could memorize all 57) which should be enough for emergency use as tabulated for July 1st so that the values will be reasonable for the whole year. Fortunately this included the three stars used in this exercise. So now adding the SHA of Vega, 80º 41' we end up with the GHA of Vega of 34º 06.7' and using the D.R. as the A.P. we get an LHA of 274º 48' and the declination of 38º 47' N. (rounded to the whole minute)
Using these values on my Bygrave slide rule (see attached work sheet) since I have no tables with me, I computed Hc of 23º 59'.
The Hs given was 24º 05.5' Computing the dip correction in my head of 4.5' (the square root of 20 must be between 4 and 5 ) and applying the refraction correction of minus 2 gives an Ho of 23º 59' giving and intercept of zero and an azimuth of 58.1 º. I long ago memorized the refraction table for altitudes above 10º in The Air Almanac and in H.O 249, the cutoff values are 63-33-21-16-12-10º , zero above 63, 1 above 33, 2 above 21, 3 above 16, 4 above 12 and 5 above 10.
I used the same procedure for Spica and Pollux getting another zero intercept for Pollux, Zn of 290.2º and a 4 NM away for Spica with a Zn of 171.7º.
Since I am on the road I do not have any of my plotting tools with me so I had to make do with what I found in my briefcase. I used my MB-2A flight computer since it had an azimuth scale and I used a pad of paper with a right angle at the corner as my straight edge for plotting the LOPs. I used a tape measure from IKEA to measure the length of the intercept (see photo.) I plotted the LOPs and found the fix by bisecting the three angles giving a fix .4 NM west of the A.P. (D.R.) and 2.8 NM north of it. (Plotting a fix as a distance from the A.P. like this is common in aerial practice and it is often done on an E-6B.) Adding the 2.8 NM north to the D.R. latitude gives a fix latitude of 34º 16' North. To convert the .4 NM west to a longitude you divide the .4 NM by the cosine of the latitude, .82, to find the difference in longitude of .5' so the fix longitude is 119º 19.5' West (rounded to either 119º 19' or 20'.) ( I got the cosine of 34º by finding the sine of 56º on the MB-2A sine scale, used for wind correction calculations.)
My fix might not be in agreement with others but I used a refraction table tabulated in whole minutes, I only memorized the stars' positions to the nearest minute and I did not have any plotting tools to use but my position is certainly good enough for emergency navigation and done without an almanac, tables or electrons.
(I will have to send the images when Ii figure out how to make them smaller.)
gl"
The first thing I memorized was the GHA of Aires at 0000 Z January 1, 2008 which is 100º 01.9' and also remembering that Aires advances 59.139' each day. With this information you can calculate GHA Aires for 0000 Z on June 9, 2008 which is the 161st day of the year but is only 160 days from January 1st. So multiplying 59.139' times 160 days gives 157º 42.2' to which you add the starting value of 100º 01.9' to come up with the GHA Aires on June 9th at 0000 Z of 257º 44.1'. To this you add the change of GHA for the time since 0000 Z (3 hours 42 minutes 10 seconds for the Vega shot) by multiplying the time interval by the rate of change of 15.041º per hour making 55º 41.6' making the GHA Aires at the time of the Vega shot of 313 º 25.7'.
I also memorized the SHAs and the Declinations of ten of the navigation stars ( nobody could memorize all 57) which should be enough for emergency use as tabulated for July 1st so that the values will be reasonable for the whole year. Fortunately this included the three stars used in this exercise. So now adding the SHA of Vega, 80º 41' we end up with the GHA of Vega of 34º 06.7' and using the D.R. as the A.P. we get an LHA of 274º 48' and the declination of 38º 47' N. (rounded to the whole minute)
Using these values on my Bygrave slide rule (see attached work sheet) since I have no tables with me, I computed Hc of 23º 59'.
The Hs given was 24º 05.5' Computing the dip correction in my head of 4.5' (the square root of 20 must be between 4 and 5 ) and applying the refraction correction of minus 2 gives an Ho of 23º 59' giving and intercept of zero and an azimuth of 58.1 º. I long ago memorized the refraction table for altitudes above 10º in The Air Almanac and in H.O 249, the cutoff values are 63-33-21-16-12-10º , zero above 63, 1 above 33, 2 above 21, 3 above 16, 4 above 12 and 5 above 10.
I used the same procedure for Spica and Pollux getting another zero intercept for Pollux, Zn of 290.2º and a 4 NM away for Spica with a Zn of 171.7º.
Since I am on the road I do not have any of my plotting tools with me so I had to make do with what I found in my briefcase. I used my MB-2A flight computer since it had an azimuth scale and I used a pad of paper with a right angle at the corner as my straight edge for plotting the LOPs. I used a tape measure from IKEA to measure the length of the intercept (see photo.) I plotted the LOPs and found the fix by bisecting the three angles giving a fix .4 NM west of the A.P. (D.R.) and 2.8 NM north of it. (Plotting a fix as a distance from the A.P. like this is common in aerial practice and it is often done on an E-6B.) Adding the 2.8 NM north to the D.R. latitude gives a fix latitude of 34º 16' North. To convert the .4 NM west to a longitude you divide the .4 NM by the cosine of the latitude, .82, to find the difference in longitude of .5' so the fix longitude is 119º 19.5' West (rounded to either 119º 19' or 20'.) ( I got the cosine of 34º by finding the sine of 56º on the MB-2A sine scale, used for wind correction calculations.)
My fix might not be in agreement with others but I used a refraction table tabulated in whole minutes, I only memorized the stars' positions to the nearest minute and I did not have any plotting tools to use but my position is certainly good enough for emergency navigation and done without an almanac, tables or electrons.
(I will have to send the images when Ii figure out how to make them smaller.)
gl"
