With any sort of sighting system, the shooter must accustom himself to the idea that he looks along a straight line, but the trajectory of his projectile is a curve, and he must therefore endeavor to bring the line of sight and the curve of the trajectory into such coincidence as is suitable for his needs. Generally speaking, the field shooter does not adjust his sights in the field, but rather sets them so that he need not consider the curve of the trajectory at practical ranges.

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Most field shooting is not precision shooting. A lot of people believe that marksmanship is all about that one precise hit on a small target at any range. To be fair, that is a great demonstration of marksmanship and precision, but you need to be aware of the limitations.

Most practical shooters, from big game hunters to military members, do not have the luxury of time to check distance, adjust sights, and take a precisely aimed shot.

In the real world, targets actively try to avoid being shot and they won’t expose themselves long enough for you to go through all those steps. In the 1950s, the Army’s ORO researched how people get shot, and the number one factor was exposure time. So the challenge for the shooter is balancing accuracy requirements against available time.

The Point Blank Zero is one of the most important methods for doing this. You’ve probably seen it called many things, including the Battlesight Zero (BZO) or Maximum Point Blank Range (MPBR). These are all correct, and reference a sighting method that takes advantage of projectile ballistics.

## The Ballistic Arc

As Col Cooper said in his excellent book, The Art of the Rifle, * bullets do not travel in straight lines*. When you fire a projectile, it moves in a curve known as a ballistic arc.

A lot of new shooters believe that a bullet rises for some distance after leaving the muzzle before it begins to fall again. To be fair, for an external viewer, that does appear to be what happens. But the catch is that it’s not the bullet design or the way the barrel is mounted that causes it.

The rifle’s sights are not level with one another. When you aim at a target in front of you the slightly shorter front sight means you naturally point the tip of the barrel a little higher. So, in short, you create an initial launch angle for the bulle

Zeroing a rifle means that you’re picking a point along the bullet’s ballistic arc that intersects with your line of sight.

### Ballistic Trajectories

The nice thing about ballistic trajectories is that they are **predictable.**

If you know the velocity, launch angle, and aerodynamic efficiency of the bullet, you can reasonably predict the flight path of the bullet.

This is another chart created by the internet ballistics guru, Molon. It shows the ballistic arc of the same projectile launched at different angles. Each angle corresponds to a different zero.

Look at each of the three arcs, and pay attention to how high the bullet travels over the line of sight. The highest point over the line of sight is the **Maximum Ordinate, **also called an Apogee. I’ve seen both get used interchangeably.

Also notice how the launch angle increases as the far intersection gets further away. By far intersection, I mean the *second *time the bullet crosses the line of sight. That’s important.

Something else you might notice is that the apogee of the bullet for a 100-meter zero occurs right 100 meters. This has some benefits for practical rifle usage, but I’ll come back to that.

When you establish a **point blank zero**, you choose a curve shape where the bullet stays within a certain distance above or below the point of aim. Velocity is a huge part of this as well since more velocity shrinks the group size.

The size of the vital zone you choose will affect the usable point blank range. Sure, you can start aiming higher or lower on the target to compensate– but then you’re no longer using the point blank zero as designed.

Remember, the goal of the point blank zero is to *remove* the guesswork. Aim at center mass of the target and fire. If you’ve chosen your vital zone size and zero well, the rest will take care of itself.

## Point Blank Zero in Practice

Consider a vital zone of eight inches in some large game animals. The point blank zero would be setting in which the bullet impacts no more than four inches above or below the center of the vital zone. The distance from the muzzle, point blank, to the maximum distance before the bullet falls below vital zone threshold is the *Maximum **Point Blank Range.*

A larger vital zone means a more generous point blank zero and a longer usable distance for the zero. A smaller vital zone means a more limited MPBR.

### Running the Numbers: Establishing MPBR

Your best tool for figuring out a point blank zero is a ballistic calculator. My favorite is JBM Ballistics, but there are many out there that you can install on your phone as well. All you need to do is feed it your data and the desired “vital zone” radius.

For this chart, I am using a Sierra 69gr SMK fired at 2750 fps. I established that velocity from a my Magnetospeed in on a 20″ rifle. I’ll work with a desired vital zone radius of six inches. That means above or below the line of sight, so there is a 12-inch total vital zone.

With these values, JBM tells me exactly what the calculated point blank zero should be for my desired 12″ zone: 291 yards.

It also tells me I can maintain my center mass hold, the MPBR, all the way out to 341 yards.

As a bonus, JBM also predicts the maximum ordinate at 161 yards.

If I go back into the calculator again using the same ballistic data and set my zero to 291 yards, you can follow the arc of the bullet using this drop chart. I’ve shaded the important area in red.

## Point Blank Zero on Paper

Ok, I’ve shown you the numbers, so it’s not just an opinion. But the numbers are one thing, how does this actually work for real life?

Zeroing at exactly 291 yards isn’t very practical, but it works as a guideline. Increasing my point blank zero to 300 yards gives me about the same result, with a drop of 6.2 inches at 350 yards.

To see how velocity affects MPBR, I made this little graphic. It shows three barrel lengths all zeroed for 300 meters, the red dot. The black dots indicate impact points at other distances.

Using this data, it’s easy to see why the Army and Marines were drawn to the 300-meter zero as their “do-all” for so long. However, one challenging aspect of this battlesight zero is the maximum ordinate.

With this zero, the bullet will be about 6 inches above the line of sight at 161 yards. If you want to hit a small target, such as a small gong or a headshot, then aiming center mass of that target means your shot might go over the target entirely.

If your target is smaller, then you need to adjust your radius and zero to compensate.

This is the reason for the common 50/200 zero. A lot of military trainers noticed that soldiers tended to miss high during engagements with the 300- meter zero. The 50/200 keeps the bullet trajectory within +/- 2 inches of the line of sight until about 250 yards.

Theoretically.

I made a similar chart for that zero as well.

Note that the cluster of shots is significantly tighter here, but that comes at the expense of losing the 400 meter impact all together. The lesson here is that you need to know your realistic envelope for engagement and plan for it.

Just for fun, I ran the numbers through JBM for my 20″ rifle and a 2″ radius vital zone (for a total of 4″ vital zone circle). The result is a point blank zero of 194 yards and a maximum point blank range of 226 yards. I highlighted that in yellow.

The red highlight shows the numbers for a 200-yard zero.

### Near and Far Intersection

Remember that your zero is the the point where the ballistic arc of the bullet intersects your point of aim. For just about every zero distance outside of 100 meters, there are actually two points where the bullet crosses your line of sight.

In the above chart, for about a 200-yard point blank zero, you’ll notice that the bullet starts 1.5″ low at the muzzle. That’s because of the sight offset, where the rifle’s sights sit 1.5″ above the bore of the rifle. Because of the launch angle on our way to a 200-yard impact, you’ll notice that the *first *intersection of the bullet and line of sight happens around 30 yards.

The trajectory’s apogee happens around 115 yards, and then the bullet arcs downward again to reach the second intersection at 200 yards.

This is where people get the idea of 50/200 or 36/300-zeroes. They’re trying to define the near and far intersections as a way of saying that if you zero at 50 yards, then you’ll also be on at 200.

Well, as all of these charts should illustrate, that’s not true. The curve depends a lot on the ballistic characteristics of the bullet as well as the velocity it’s traveling. You can get close, even just a few tenths of an inch away, but *close isn’t a zero*.

So never assume that you’re “good to go” with multilple zeroes. Your zero is the distance you’ve actually verified at. If you want to zero at 25 yards, then fine, but don’t think you’re also zeroed at 300 until you actually test your rifle at 300.

## Applying Point Blank Zero to Optics

With enough practice, you will learn your MPBR well. You’ll begin to recognize situations where you can just “hold center” as my PRS-shooting podcast guest put it, or have to dial your scope.

Point blank zero works particularly well for red dot sights or magnified scopes with standard duplex crosshairs. But what about other reticle designs? You can combine point blank zero with different reticle shapes to determine more aiming points as well.

For instance, my Trijicon TR24G has a glowing triangle sitting atop a post. However, the heavy post prevents me from using holdovers beyond the bottom edge of the triangle

According to Trijicon, this triangle is 4.2 MOA tall at 4x magnification. Since it is second focal plane, it is 12.8 MOA at 1x, and 8.4 MOA at 2x magnification.

JBM does not produce a point blank zero based on minutes of angle. But it does still produce MOA drop values.

You’ll need to play with the distances until you arrive at an acceptable solution.

If I wanted to keep my impacts to 4.2 MOA above or below the tip of the triangle, then a 275-yard zero works best. Rounding up to a 300-yard zero with the tip of the triangle means that the bottom of the triangle is at about 410 yards.

If I zoom down to 2x, the bottom of the triangle is now 8.4 MOA from the tip, which correlates to a 500-yard aim point. At 1x, that same point now gives about a 600-yard aim point.

That is, of course, assuming you can even see the target.

This method works reasonably well for any optic. If you happen to have a BDC or any reticle that provides solid holdover points, then you might use that method instead.

## Multiple Aiming Points

There is another technique related to the point blank zero but isn’t quite the same thing. The Swiss developed a method of aiming at the belt line or the neck depending on the estimated range to the target.

They use a 300-meter zero. If the target is “close,” then the shooters aims for the belt. With that aiming point, any missed shots will hit higher, and hit center mass.

If the target is “far,” then the shooter aims at the neck. Shots will fall low and also into center mass.

This technique is Sniping 4th Generation, and it’s used to teach recruits in a single day how to reach an 80% effective hit rate out to 600 meters. If you’re interested in learning more, you can read my write up on the technique.

## The Zen of the 100-Meter Zero

A 25-yard zero keeps me +/- 3 inches out to 250 yards. That’s a good and usable point blank range.

But let’s get away from the numbers and talk about the simple 100-meter zero. If you recall from the ballistic chart earlier, a 100-meter zero correlates to the maximum ordinate. Put another way, if you zero for 100 meters, then the bullet will never cross *above* your line of sight.

With a point blank zero set at 200 or 300 meters, there are situations where you have to remember to aim *lower*, or your bullet will sail over the target. Under stress, you might forget to do that. Missing high gives you no reference for where you *should* have aimed.

If you zero for 100 meters, then the bullet will only fall below the point of aim and hit the dirt in front. You can use the impact of missed shots to walk your next shots in.

## Wrapping Up

In the end, you have to imagine two opposing ends of a line. On one end is speed, and on the other is precision.

Which is more important to you for the most likely shot you are going to take?

Point blank zeroes work great for hunting or self-defense inside 200 yards on fairly large target zones. If you need to hit small targets at longer ranges, then you might need to shift more towards precision-oriented zeroing methods and optics.

I hope you found this article useful, please let me know if you have any questions or comments down below.

“… and it’s used to teach recruits in a single day how to reach an 80% effective hit rate out to 600 meters.” This sentence fragment, by itself, wraps up the entire point-blank-zero philosophy in a nutshell.

It’s funny, I was having an email exchange about that very idea. Be careful about associating PBZ/PBR too closely with S4G.

S4G has a very large vital zone, a whole human torso standing in the open, and multiple aiming points. It’s definitely a military tactic for massing effective fire than a precision marksmanship tool.

A good PBZ/PBR is going to have a much smaller vital zone, and therefore be usable in a much smaller range window (250-350 meters).

Well done sir!

Thanks, Pete! I really appreciate the insight you’ve given.

As an armorer, you should be able to help a customer zero his or her iron sights or scope

One thing I haven’t seen in many discussions about MPBR is including the effects of your system’s precision. I believe this is a contributing factor toward the 50/200 zero. Even though an animal’s vitals might be 8 inches, your system might only shoot to 2 MOA. If you want to keep everything within the vitals, you need to reduce that size to compensate (or do the detailed math). It would be interesting to see a 4 MOA dot at each of the ranges on your target plots. This would illustrate what is actually happening, especially at longer ranges like 600… Read more »

That’s a great point, honestly. All of the math accounts for “perfect” accuracy. But the margins for error change a lot when you start factoring in the rifle, ammunition, and skill of the shooter.

Fix MBPR to MPBR (Maximum Point Blank Range). Nice article though.

Hah, thanks for the catch, Ivan.

Great article Matt! The illustrations really helped visualize the math. Glad Ivan caught the ‘MBPR’ – was a tad confusing. It was the only thing I didn’t understand (thought it might be a missile target term) but knew your intent! Really well done – thanks!