Range Report CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

[goober]

I am sure somewhere here this has been discussed but I haven’t seen it yet. My question is relating to the article link below and if ballistic programs allow for this upward -sideward and down ward bullet movement due to wind, gravity and spin and how would it be different in the southern hemisphere than the northern given we also use right hand twist barrels. Another thought is at what wind speed would cause the measurement of movement as indicated by the charts? not my writings below but Interesting stuff.


Vector Wind Effect for Right Hand Twist Barrels
When shooting at long range, the bullet path is influenced by several factors, among which are Gravity, Spindrift, and Wind Velocity. Spin Drift will drift the path of the bullet to the right when fired from a barrel with a right hand rifling twist.
Wind velocity and direction affect not only the left or right deflection of the bullet but also the vertical deflection as an effect of the bullet spin. Picture the following in your mind.
With no wind and the sights adjusted to compensate for the right spin drift, the bullet would impact the target at dead center When the wind is blowing from three o'clock, visualize the right-hand-twist spinning bullet as rollingl up on the wind, causing an increase in elevation in addition to being pushed to the left. This is reflected in the chart by the circle enclosing the number '3'.
When the wind is blowing from nine o'clock, you can think of the right-hand-twist spin as causing the bullet to roll under the wind and be deflected downward in addition to being pushed to the right. The chart shows the circle containing the number '9' at the lower right. When the wind is blowing from twelve o'clock, the bullet effectively starts out with a muzzle velocity that is decreased by the value of the headwind velocity, thus requiring more time to reach the target. Consequently, gravity causes the bullet to drop farther than if there were no headwind. The circle containing the '12' is near the bottom of the chart reflecting the additional drop of the bullet.
If the wind is blowing from six o'clock, the bullet has the wind velocity added to its muzzle velocity and reaches the target sooner with less bullet drop. Number '6' is near the top of the chart indicating that a shot will go high with a tailwind.
The wind seldom blows from twelve, three, six and nine o'clock, so all the other wind directions influence vertical and horizontal deflections in proportion to their vector and velocity. The remaining circles containing the wind velocity quadrant indicate the approximate quadrant of the respective bullet strikes.
Trying to keep all of the variables straight in the mind when shooting will make one cross-eyed so the chart is for reference as to which quadrant the specific wind direction will influence the bullet path. This chart does not reflect the distance that a bullet will be moved, but only indicates the vertical and horizontal deflection that may be expected from being influence by the respective wind directions.
PLEASE PASTE LINK TO VIEW CHART

http://www.uslink.com/~tom1/windvector.htm

 

[doc76251]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

That chart is true and works north or south of the equator. The issue comes in where it's easy to "qualify" the veracity of the chart it is exceptionally difficult to "quantify" it.

As the author says "This chart does not reflect the distance that a bullet will be moved, but only indicates the vertical and horizontal deflection that may be expected from being influence by the respective wind directions."

Most folks do not shoot often enough, or become sufficiently proficient at the distances where these effects become noticeable to correct for them effectively.

Cheers,

Doc

 

[goober]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

Doc, would the southern hemisphere produce a chart oppersite to the one shown in link? Does a ballistic programe account for this climbing action and at 1000 yards with a 10 @3 wind what kind of movement are we talking about -i havent a clue so it would be good to shine a litle light on this .regards

 

[Lindy]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

The chart refers to spin drift, gravity, and wind drift. Coriolis effect is what is different in the northen and southern hemispheres, and is not addressed by that diagram.

Nor is the Eötvös effect, which depends upon the direction one is shooting and the lattitude.

With respect to the ballistic programs, some estimate the effect of spin drift, and some do not. Some correctly model the effect of head or tailwinds on elevation, but not all do.

 

[The Mechanic]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

The ABC (cheytac) (Advanced Ballistic Calculator) is supposed to take into account their balanced flight, controlled spin technology to get more range. Basically like a football turns nose down on a good throw. This is a HUGE oversimplification.

 

[goober]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

I wondered with what the chart showed how much I would be affected at 1000 yards with these movement 1/ spin drift being negligble due to being in southern hem and having a right twist barrel
2/ given that spin drift is apparent no matter what but more or less made to be negligble point of impact change due to being offset in the southern situation -how much does a bullet climb up or down a 10@ 3 wind and is it to the oppersite side of the said chart ? I hope I am making sense and not just sounding like a dick wad

 

[TiroFijo]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

These variations in POI are clearly explained in "Rifle Accuracy Facts" by H.R.Vaughn, pages 195-198, complete with a test example, and NUMBERS to estimate it (the magnitude varies with the gyroscopic stability value). It is due to a combination of gyroscopic effects + side wind vector component.

It has nothing to do with the hemisphere, latitude or shot orientation, as Lindy has already mentioned.

Now, the example he shows is at short range (200 yds), and ALL the references of these variations I've seen mentioned were for bench rest, up to 300 yds or so. Theoretically you get the same effects even at long range, but I have never seen any theoretical work, program, or shooting tests that attempt to put NUMBERS to the magnitude of these POI variations due at long range.

I would love to see some work done on this effect at long range.

 

[Lindy]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

<div class="ubbcode-block"><div class="ubbcode-header">Quote:</div><div class="ubbcode-body">I would love to see some work done on this effect at long range.</div></div>

You'd need an indoor or underground range to isolate the tests from the effects of the wind.

I have heard of someone building an underground range that was at least a mile, but I don't recall who. Probably a government agency.

Since the effects we're talking about are mostly outweighed by the effect of a 1 mph crosswind, I find them of mostly intellectual curiosity.

 

[CoryT]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

As it happens, FFS does in fact have this as a built in refinement calculation. At 1900 yards under my home range conditions, a 250gr 338 LM gets .1 mil up/down for a 10mph wind from 90/270. Since .1 mil at 1900 yards is about 7", I do leave that feature turned on.

However, a 20fps velocity change is worth .3 mil at the same range. Since you can't know in advance what the actual velocity of a given round will be, I'm not sure that being able to caluculate that .1 mil into the final solution has any measurable effect on the solution for a single shot.

 

[Lindy]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

Indeed, there are limits to the accuracy of what we calculate - there are other sources of ballistic program inaccuracies.

 

[TiroFijo]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

Cory, that's a good analysis, thanks

The effect seems to be very minor.

Do you have other examples, say for a .308 175 gr SMK at 1000 yds, and a .308 190 gr SMK at 1300 yds?

The value of these vertical variations of POI due to a side wind component depend on the gyroscopic stability value (GS), and this in turn depends on the particular bullet, velocity, twist, and environmental conditions. And since GS also varies downrange because the rotational speed decay is slower than the linear speed, it all gets very complicated... I don't think the FFS program takes all this into account, perhaps it gives a rough number based on a simplified analysis.

In Vaughn's exmple the drift angle is 15º to 20º with normal GS values at the muzzle, this means that the vertical POI variation due to a side wind at 200 yds is about 25-34% that of the horizontal, very large indeed!! With a 308 and a full value 10 mph this is a vertical POI variation of 0.85"-1.1".

It has always puzzled me why this has a very small effect at long range... or perhaps not so small, but we just can't see it even if it is there.

 

[BryanLitz]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

<div class="ubbcode-block"><div class="ubbcode-header">Originally Posted By: Lindy</div><div class="ubbcode-body"><div class="ubbcode-block"><div class="ubbcode-header">Quote:</div><div class="ubbcode-body">I would love to see some work done on this effect at long range.</div></div>

You'd need an indoor or underground range to isolate the tests from the effects of the wind. </div></div>

This is what modeling and simulation is for.

Normal ballistics programs don't account for the effect being discussed (I'd like to see how FFS handles it). It takes a full 6-dof simulation to model the components that are truly responsible for this behavior.

I have examined this behavior with my 6-dof model. I'll do my best to explain.

Step one is to understand why the vertical displacement happens in the first place. The bullet is not 'rolling on the crosswind' as described in the link above. Rather, when the bullet enters a crosswind, it's forced to realign it's nose (weathervane) into the oncoming air flow. When the bullet's nose turns, there is a gyroscopic reaction which results in a predictable precession pattern. The result of this process is a vertical 'jump', caused by the net effect of the bullets precession 'steering' it up or down based on twist and wind direction. The key here is to understand that the vertical deflection is a 'jump', which happens within tens-of-yards from the muzzle. <span style="font-style: italic">Once the jump has been established, <span style="text-decoration: underline">it's a fixed angular deflection for the rest of the trajectory</span>.</span>

Let's examine the consequence of the above statement. Let's say a bullet has .6" of wind deflection at 100 yards in a 10 mph crosswind. Also, let's say that the bullet has a stability factor that results in .4 MOA of vertical jump from that crosswind. At 100 yards, the deflection angle will be <span style="font-weight: bold">35 degrees</span> (atan(.42/.6). Now go to 200 yards. The wind deflection at 200 yards is now 2.7", and the vertical angle of deflection is still .4 MOA. So the angle of deflection at 200 yards is only <span style="font-weight: bold">18 degrees</span>.
Take this out to 1000 yards where the horizontal wind deflection is 94", and the angle of deflection is now only <span style="font-weight: bold">2.6 degrees</span>. The vertical deflection is .4 MOA all the way (because it was determined close to the muzzle) but the horizontal effect of that crosswind increases much more, thus yielding a shallower <span style="font-style: italic">angle</span> of deflection at the longer ranges.

I've read Vaughn's analysis of the this mechanism and was mislead by it at first. His description leads one to believe that the angle of deflection is proportional to stability factor <span style="font-style: italic">regardless of range</span>, which is misleading. I'm not saying that he didn't understand the process, just that his explanation is misleading.

Some other observations:
As mentioned above, the vertical effect of a crosswind is purely an aerodynamic effect which isn't influenced by your location or azimuth of fire in relation to the planet.
The link above is misleading in several ways.
-As already mentioned, the explanation for the vertical deflection is wrong.
-The statement about head and tail winds effectively adding or subtracting from the MV is wrong.
-The diagram shows more vertical deflection for a head/tail wind than horizontal deflection for a pure crosswind which is extremely misleading.

My explanation above is for the sterilized 'constant crosswind' textbook scenario which is useful for explaining the concepts, but is rarely how it plays out in the real world. In the real world, the bullet is encountering an ever changing wind vector which causes it to continually 'trim' it's nose angle, which results in tiny, continuous precession cycles, which in turn causes a series of small 'jumps' all along the trajectory. The textbook answer is still valuable though because the bullet encounters the biggest 'jump' right out of the muzzle when it first enters the crosswind. From there out it's small adjustments. Even in the case where the bullet encounters a complete wind direction reversal, the jump that occurs there is only important for the second half of the trajectory, where the muzzle 'jump' is more influential because it happened at the beginning.

Here's a link to a discussion on BR Central where this topic was discussed at length:
http://benchrest.com/forums/showthread.php?t=65263
'Round-about page 7 I present some 6-dof M&S results for a 'switch-wind' condition.

-Bryan

 

[Lindy]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

Good lord! Eleven pages!

Thanks for the link, Bryan. When I have a week to spare, I'm going to go back to it, and try to understand it.

But now I have a very complex explanation for missing the target...

 

[TiroFijo]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

Thanks a lot, Bryan!

 

[sharac]

Re: CLIMBING PROJECTILES IN SOUTHERN HEMISPHERE

Not to mention all this theory goes down the drain when one miss judges the wind or as it has tendency to shift when it is least needed and in direction which is worst possible. Its well worth understanding it however for practical application much more can be achieved by honing wind reading skills.