"Angle Shooting"
Correcting for the effects of gravity
By Ward W. Brien

There is a physical ballistic problem encountered when shooting on angles that causes the bullets point of impact to hit high.

Shooting on angles is what every hunter experiences while hunting in mountainous terrain. Sheep hunters and deer hunters alike know all to well, that if their target is up or down on an angle, that they must aim low because the bullet will impact high. The reason for this has to do with gravity and the adjusted site height above the bore of the barrel.

When we zero in our rifle at 100 yards, we are shooting on a flat plane with the full force of gravity pushing down on the bullet. In order to zero properly and get the bullet to strike the bulls-eye, we need to adjust the sight height above the bore of the barrel for this particular condition, (shooting on a flat plane) so that when the bullet leaves the bore of the barrel it arcs up into the full force of gravity, and then drops down onto the bulls-eye.

However, when we shoot on an incline or decline (up or down on an angle) the force and effect of gravity is less on the bullet; but the sight height above the bore of the barrel remains the same, or adjusted for shooting on a flat plane.

Because of this, the bullet will have a flatter trajectory and strike the target higher than where our intended point of aim was. It is imperative that when we are shooting up or down on an angle that we eliminate the guesswork, and correct the straight line distance to the target or "sloped distance," to the, corrected for gravity, distance to target.

Now, this is an easy adjustment; a simple equation that will put you very close to right on target. However there are three ways to obtain this and each one is more accurate than the other.

The first method is called the "field expedient" or "Rifleman Method." As an example, when a surveyor is shooting a mountain top for mapping purposes, he uses an instrument called a theodolite. The theodolite tells the surveyor the angle of his aim. His/her goal is to obtain the base of the triangle distance. Hence, simple geometry comes into play. The surveyor notes the angle that he is holding at, then goes to his data book and obtains a cosine number of that angle, which he then multiplies to the sloped distance.

Figure 2

In figure 2, you can see the sloped distance to target equals 500 yards and the angle that the hunter is holding on is 30 degrees (cosine number of .87). To obtain the bottom leg of the triangle, you would multiply the cosine number of .87 to the 500 yards. (.87 X 500 yds. = 435 yds.) This gives you the straight line distance as if you were shooting on a flat plane, with the full force of gravity affecting the bullets path of flight. However, the "Rifleman Method" does not take into account the fact that the bullet is still traveling the full distance to target, retaining it's time of flight. Because of this, the Rifleman Method is not adequate for long distance shooting, however the other methods are; and we will cover them shortly.

Below in figure 3, referencing a .300 Remington Ultra Mag, utilizing a flat shooting 180 grain Nosler Partition bullet, with a velocity of 3250 feet per second, the uncorrected for gravity distance of 500 yards to target would cause the bullet's point of impact (under the field expedient method) to hit approximately 13.2 inches high; or 1.75 minute of angle. Please see the Exbal Software Generated Angle Drop chart below in figure 3.

To the average hunter, these trajectories, at first, may not appear to be significant, but as an experienced hunter you know that they are; and the angle that you will be holding on demands a correction. As an example, let's say that your rifle shoots an average group size of one inch at 100 yards (large for a pro-grade rifle). At three hundred yards the group size will open to three inches; at five hundred yards, five inches. So, if you are going to be thirteen inches high at 500 yards if uncorrected for gravity, then you can add an additional five inches to that, theoretically, in any direction. This is not difficult to see; math is math and science is science and when the math is done correctly, one round will put one animal down.

Drop Chart Excluded

Figure 3 - Angle Drop Table for the 300 Rem Ultra Mag Excluded

The U.S. Military as well as other Government agencies, train all of their Precision Marksmen on how to obtain the corrected for gravity distance to target. The original method of approach was to utilize a Protractor, string and paper-clip. The string was tied to the center of the protractor and weighted with the paper-clip. When the Marksman was aiming at his target, the protractor was held in place with the weighted string along the side of the receiver inline with the barrel. The Marksmen would then carefully grab the protractor and string, and obtain the angle that he was holding on. Then, the Marksman would go to his data book and obtain the cosine number, then do the math; very simple and very straight forward. Only today there is an easier, faster and more dependable method of obtaining the cosine number; and that is by using an "Angle Cosine Indicator" manufactured by "Sniper Tools Design Company."

The Angle Cosine Indicator, (ACI) pictured in figure 4, is a widely excepted method of obtaining the cosine number of the angle that the hunter is holding on, by all Branches of the U.S. Military and militaries throughout the world.

Figure 4

It is a simple tool for hunters who hunt in mountainous terrain and is a vault solid precision instrument. It is manufactured from aircraft grade aluminum and anodized a flat black color. It fastens onto your rifle or your scope; either by a standard Weaver Base scope ring, or as seen in figure 4, by "Badger Ordnance's" military specific picantinny rail mount. When the rifle is held on target, the "ACI" indicates the cosine number of that angle by means of a highly visible index mark; in addition, the cosine numbers transverse the body in five degree increments. The ACI is easily zeroed to your rifles bore by simply loosening the side screw and rotating the body until the zero cosine number sits inline of the index mark.

To install the Angle Cosine Indicator you will first need to decide on your method of mounting; either a Weaver base scope ring or a Badger Ordnance's Picantinny rail mount. Once that is decided, you will level the bore of your barrel by placing a spirit bubble level on the inside rail of your receiver, which is where your bolt lugs ride on. Once the bore is level, install and zero the ACI, insuring that it is indeed level with the bore of the barrel and the zero cosine number is sitting ontop of the index mark. Once that is accomplished, you are ready to hunt. The following is the procedure for utilizing the ACI while in the field.

As previously discussed; with the Rifleman Method, you spot your target. 2) Range / obtain the distance to your target by either utilizing a laser range finder or a ranging reticle. 3) Aim at your target and then look off to the side of your rifle at the Angle Cosine Indicator and obtain the indicated Cosine number. 4) Multiply the cosine number to your distance to target, which will give you you're straight line distance (bottom leg of the triangle) or estimated, corrected for gravity distance. Now, look at your data card to obtain your hold for the corrected target distance, and adjust your turrets as specified.

In the second method of obtaining the corrected for gravity distance to target, known as the "Improved Rifleman Method," the ACI still plays its role, however the cosine number is multiplied to your minute of angle (MOA) or mil-radian (MILRAD) hold for the specified distance. This is more accurate than the Rifleman method.

In the third method of obtaining the corrected for gravity distance to target, the ACI again plays its role, however the indicated cosine number is inputted into the "Exbal" Ballistic Targeting Software which delivers the exact, scientifically correct hold. "Exbal" is written by Gerald Perry of "Perry-Systems," and is ported to run on three different platforms; 1) Mobile Windows based Pocket PC; 2) Windows PC desk top and 3) Palm Pilot PDA. The Windows based Pocket PC such as the Dell Axim 30 (624 MHz) is what I strongly recommend. This is the most accurate method of use available because the software takes into account the trigonometry of the fact that the bullet will still travel the full distance to target, will maintain a similar time of flight and is comingled with the fact that each projectile (bullet) has it's on ballistic coefficient (BC) and Deceleration Curve (DC). There can be as much as an eight (8) minute of angle error when using the Rifleman method.