Sierra ballistics calculator

Our free Ballistic Calculator generates thousands of shot simulations using your provided sierra ballistics calculator, muzzle velocity, and real-world environmental conditions to create the most accurate bullet drop compensation data available. You're not currently signed in. You'll need to Sign In or create a Ballistix Account if you'd like save your calculation data.

Use this ballistic calculator in order to calculate the flight path of a bullet given the shooting parameters that meet your conditions. This calculator will produce a ballistic trajectory chart that shows the bullet drop, bullet energy, windage, and velocity. It will a produce a line graph showing the bullet drop and flight path of the bullet. By adding trajectories to the panel on the right you may produce charts and graphs that show the different trajectories side by side. This can be useful in comparing cartridges or loads. Keep in mind this is an approximation and although it is quite accurate it should never replace first-hand experience of shooting your specific firearm and ammunition to determine the bullet drop and windage at different ranges and conditions.

Sierra ballistics calculator

The basic elements of a trajectory and the information contained in the tables are described below. We have included the most useful trajectory parameters velocity, energy, drop, bullet path, wind drift and point blank range with the zero range to maximize it in the Infinity tables. For each computed trajectory, they are tabulated for the user-selected muzzle velocity and shooting conditions. This discussion uses an example of a popular rifle bullet to discuss each element of the baseline table and explain the important terms. Trajectory: The trajectory of a projectile, in this case a rifle bullet, is the actual path that the projectile follows after leaving the muzzle. It is very important that this term be understood before using the tables. The trajectory of the bullet is shaped by many factors: gravity, altitude air pressure , temperature, humidity, muzzle velocity, wind conditions, and the ballistic coefficient of the bullet itself. Although all of these have been discussed in much more detail in previous sections, the major contributors will be redescribed here as they affect the example trajectory. The figure above illustrates the parts of a trajectory as they are discussed here and used in the tables. As soon as the bullet leaves the muzzle, gravity causes it to begin to fall away from its line of departure. This creates the drop discussed later. The line of departure is an imaginary line through the longitudinal centerline Bore Centerline of the bore and is the line upon which the bullet is launched. The significance of this line will be discussed as each element of the tables is discussed.

The line of departure is an imaginary line through the longitudinal centerline Bore Centerline of the bore and is the line upon which the bullet is launched. The deflection sierra ballistics calculator the bullet due to crosswind is related to the crosswind velocity or crosswind component of a wind from any direction and the time of flight of the bullet, sierra ballistics calculator. Keep in mind this is an approximation and although it is quite accurate it should never replace first-hand experience of shooting your specific firearm and ammunition to determine the bullet drop and windage at different ranges and conditions.

Use this ballistic calculator in order to calculate the flight path of a bullet given the shooting parameters that meet your conditions. This calculator will produce a ballistic trajectory chart that shows the bullet drop, bullet energy, windage, and velocity. It will a produce a line graph showing the bullet drop and flight path of the bullet. By adding trajectories to the panel on the right you may produce charts and graphs that show the different trajectories side by side. This can be useful in comparing cartridges or loads.

Bullet library includes all major bullet companies as well as ammunition companies and allows for addition of new and custom bullets. Both are retired Chief Scientists from a major aerospace company. This program is available in CD-Rom format only. Interface and program architecture design by Rodney Korn. The program does much more than compute bullet trajectories. It contains a feature that computes the effects on the bullet trajectory of variations in firing conditions. For example, you can change altitude of the firing point, and compute the effect on the trajectory. Or you can change a wind condition; or muzzle velocity; or Ballistic Coefficient. In fact, you can change any inputted firing condition or combination of conditions.

Sierra ballistics calculator

Use this ballistic calculator in order to calculate the flight path of a bullet given the shooting parameters that meet your conditions. This calculator will produce a ballistic trajectory chart that shows the bullet drop, bullet energy, windage, and velocity. It will a produce a line graph showing the bullet drop and flight path of the bullet. By adding trajectories to the panel on the right you may produce charts and graphs that show the different trajectories side by side. This can be useful in comparing cartridges or loads. Keep in mind this is an approximation and although it is quite accurate it should never replace first-hand experience of shooting your specific firearm and ammunition to determine the bullet drop and windage at different ranges and conditions. To make it as accurate as possible, it is important that you input the most accurate information that represents shooting conditions, your firearm, and cartridge. The two most important variables are the Initial Velocity and the Ballistic Coefficient.

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There could be an impact at the longer ranges due to the increased time of flight over the slightly longer flight path. Please sign up for our newsletter so that you can be alerted the moment these new features are launched! Sign Up. Please let me know how it can be improved upon. Drag Function: G1 Ballistic Coefficient: 0. Keep in mind this is an approximation and although it is quite accurate it should never replace first-hand experience of shooting your specific firearm and ammunition to determine the bullet drop and windage at different ranges and conditions. Ballistic Resources Gain a deep knowledge of ballistic science and access our improved ballistic calculator. If a specific zero is required, we find those with a secant method root-finding algorithm. Once you've completed the form click the calculate button to generate your ballistic compensation drop chart. It is very important that this term be understood before using the tables. In that sense, they are better than a pure point mass calculator, which ignores spin. Where did you get your ballistic coefficients?

The Bison Ballistics calculator is a modern ballistics calculator for sportsmen. To use it, just pick a bullet from our library, fill in the appropriate information and click "Calculate".

I want to learn more about ballistics. Zero Range The range at which the bullet's path will intersect with your line of sight. Running the Maximum Point Blank Range Operation in Infinity will tell you where to zero your gun to maximize the point blank range, as the example below shows. Ballistic Trajectory Calculator Use this ballistic calculator in order to calculate the flight path of a bullet given the shooting parameters that meet your conditions. Enter a BC and matching drag function, or select a bullet from the library and then enter the following variables:. Show Sound Barrier: [? This calculator will produce a ballistic trajectory chart that shows the bullet drop, bullet energy, windage, and velocity. Drop , as it is used in ballistic computations, is really an intermediate parameter. Ballistic Coefficient: [? These two points determine the line of sight with respect to the gun and permit an accurate calculation, using the drop, of the bullet position with respect to the line of sight. Wind Heading The direction of the wind. Relative Humidity: [? This is the result of the bore being lower than the scope's line of sight.