Field of the Invention
The present invention relates to optical instruments and methods for aiming a rifle, external ballistics and methods for predicting projectile's trajectory. This application relates to projectile weapon aiming systems such as rifle scopes, to reticle configurations for projectile weapon aiming systems, and to associated methods of compensating for a projectile's external ballistic behavior while developing a field expedient firing solution.
Discussion of the Prior Art
Rifle marksmanship has been continuously developing over the last few hundred years, and now refinements in materials and manufacturing processes have made increasingly accurate aimed fire possible. These refinements have made previously ignored environmental and external ballistics factors more significant as sources of aiming error.
The term “rifle” as used here, means a projectile controlling instrument or weapon configured to aim and propel or shoot a projectile, and rifle sights or projectile weapon aiming systems are discussed principally with reference to their use on rifles and embodied in telescopic sights commonly known as rifle scopes. It will become apparent, however, that projectile weapon aiming systems may include aiming devices other than rifle scopes, and may be used on instruments or weapons other than rifles which are capable of controlling and propelling projectiles along substantially pre-determinable trajectories (e.g., rail guns or cannon). The prior art provides a richly detailed library documenting the process of improving the accuracy of aimed fire from rifles (e.g., as shown in
Most shooters or marksmen, whether hunting or target shooting, understand the basics. The primary factors affecting aiming accuracy are (a) the range or distance to the target which determines the arcuate trajectory or “drop” of the bullet in flight and the time of flight (“TOF”), and (b) the windage, wind deflection factors or lateral drift due to transverse or lateral forces acting on the bullet during TOF. All experienced marksmen account for these two factors when aiming. Precision long-range shooters such as military and police marksmen (or “snipers”) often resort to references including military and governmental technical publications such as the following:
A number of patented rifle sights or projectile weapon aiming systems have been developed to help marksmen account for the elevation/range and windage factors when aiming. For example, U.S. Pat. No. 7,603,804 (to Zadery et al) describes a riflescope made and sold by Leupold & Stevens, Inc., with a reticle including a central crosshair defined as the primary aiming mark for a first selected range (or “zero range”) and further includes a plurality of secondary aiming marks spaced below the primary aiming mark on a primary vertical axis. Zadery's secondary aiming marks are positioned to compensate for predicted ballistic drop at selected incremental ranges beyond the first selected range, for identified groups of bullets having similar ballistic characteristics.
Zadery's rifle scope has variable magnification, and since Zadery's reticle is not in the first focal plane (“F1”) the angles subtended by the secondary aiming marks of the reticle can be increased or decreased by changing the optical power of the riflescope to compensate for ballistic characteristics of different ammunition. The rifle scope's crosshair is defined by the primary vertical line or axis which is intersected by a perpendicular horizontal line or primary horizontal axis. The reticle includes horizontally projecting windage aiming marks on secondary horizontal axes intersecting selected secondary aiming marks, to facilitate compensation for the effect of crosswinds on the trajectory of the projectile at the selected incremental ranges At each secondary aiming mark on the primary vertical axis, the laterally or horizontally projecting windage aiming marks project symmetrically (left and right) from the vertical axis, indicating a windage correction for wind from the shooter's right and left sides, respectively.
Beyond bullet drop over a given range and basic left-right or lateral force windage compensation, there are several other ballistic factors which result in lesser errors in aiming. As the inherent precision of rifles and ammunition improves, it is increasingly critical that these other factors be taken into consideration and compensated for, in order to make an extremely accurate shot. These factors are especially critical at very long ranges, (e.g., approaching or beyond one thousand yards). Many of these other factors were addressed in this applicant's U.S. Pat. No. 7,325,353 (to Cole & Tubb) which describes a riflescope reticle including a plurality of charts, graphs or nomogrpahs arrayed so a shooter can solve the ranging and ballistic problems required for correct estimation and aiming at a selected target. The '353 patent's scope reticle includes at least one aiming point field to allow a shooter to compensate for range (with elevation) and windage, with the “vertical” axis precisely diverging to compensate for “spin drift” and precession at longer ranges. Stadia for determining angular target dimension(s) are included on the reticle, with a nomograph for determining apparent distance from the apparent dimensions being provided either on the reticle or external to the scope. Additional nomographs are provided for the determination and compensation of non-level slopes, non-standard density altitudes, and wind correction, either on the reticle or external to the riflescope.
The elevation and windage aim point field (50) in the '353 patent's reticle is comparable, in one respect, to traditional bullet drop compensation reticles such as the reticle illustrated in the Zaderey '804 patent, but includes a number of refinements such as the compensated elevation or “vertical” crosshair 54, which can be seen to diverge laterally away from a true vertical reference line 56 (e.g., as shown in FIG. 3 of the '353 patent), to the right (i.e., for a rifle barrel with rifling oriented for right hand twist). The commercial embodiment of the '353 patent reticle is known as the DTAC™ Reticle, and the RET-2 version of the DTAC reticle is illustrated in
The compensated elevation or “vertical” crosshair of the DTAC™ reticle is useful for estimating the ballistic effect of the bullet's gyroscopic precession or “spin drift” caused by the bullet's stabilizing axial rotation or spin, which is imparted on the bullet by the rifle barrel's inwardly projecting helical “lands” which bear upon the bullet's circumferential surfaces as the bullets accelerates distally down the barrel. Precession or “spin drift” is due to an angular change of the axis of the bullet in flight as it travels an arcuate ballistic flight path. While various corrections have been developed for most of these factors, the corrections were typically provided in the form of programmable electronic devices or earlier in the form of logbooks developed over time by precision shooters. Additional factors affecting exterior ballistics of a bullet in flight include atmospheric variables, specifically altitude and barometric pressure, temperature, and humidity.
Traditional telescopic firearm sight reticles have been developed with markings to assist the shooter in determining the apparent range of a target. A nearly universal system has been developed by the military for artillery purposes, known as the “mil-radian,” or “mil,” for short. This system has been adopted by most of the military for tactical (e.g., sniper) use, and was subsequently adopted by most of the sport shooting world. The mil is an angle having a tangent of 0.001. A mil-dot scale is typically an array of dots (or similar indicia) arrayed along a line which is used to estimate or measure the distance to a target by observing the apparent target height or span (or the height or span of a known object in the vicinity of the target). For example, a target distance of one thousand yards would result in one mil subtending a height of approximately one yard, or thirty six inches, at the target. This is about 0.058 degree, or about 3.5 minutes of angle. It should be noted that although the term “mil-radian” implies a relationship to the radian, the mil is not exactly equal to an angle of one one thousandth of a radian, which would be about 0.057 degree or about 3.42 minutes of angle. The “mil-dot” system, based upon the mil, is in wide use in scope reticle marking, but does not provide a direct measure for determining the distance to a target without first having at least a general idea of the target size, and then performing a mathematical calculation involving these factors. Confusingly, the US Army and the US Marine Corps do not agree on these conversions exactly (see, e.g., Refs 5 and 6), which means that depending on how the shooter is equipped, the shooter's calculations using these conversions may change slightly.
The angular measurement known as the “minute of angle,” or MOA is used to measure the height or distance subtended by an angle of one minute, or one sixtieth of one degree. At a range of one hundred yards, this subtended angle spans slightly less than 1.05 inches, or about 10.47 inches at one thousand yards range. It will be seen that the distance subtended by the MOA is substantially less than that subtended by the mil at any given distance, i.e. thirty six inches for one mil at one thousand yards but only 10.47 inches for one MOA at that range. Thus, shooters have developed a rather elaborate set of procedures to calculate required changes to sights (often referred to as “clicks”) based on a required adjustment in a bullet's point of impact (e.g., as measured in “inches” or “minutes”).
Sight adjustment and ranging methods have been featured in a number of patents Assigned to Horus Vision, LLC, including U.S. Pat. Nos. 6,453,595 and 6,681,512, each entitled “Gunsight and Reticle therefore” by D. J. Sammut and, more recently, U.S. Pat. No. 7,832,137, entitled “Apparatus and Method for Calculating Aiming Point Information” by Sammut et al. These patents describe several embodiments of the Horus Vision™ reticles, which are used in conjunction with a series of calculations to provide predicted vertical corrections (or holdovers) for estimated ranges and lateral corrections (or windage adjustments), where a shooter calculates holdover and windage adjustments separately, and then selects a corresponding aiming point on the reticle.
In addition to the general knowledge of the field of the present invention described above, the applicant is also aware of certain foreign references which relate generally to the invention. Japanese Patent Publication No. 55-36,823 published on Mar. 14, 1980 to Raito Koki Seisakusho KK describes (according to the drawings and English abstract) a variable power rifle scope having a variable distance between two horizontally disposed reticle lines, depending upon the optical power selected. The distance may be adjusted to subtend a known span or dimension at the target, with the distance being displayed numerically on a circumferential external adjustment ring. A prism transmits the distance setting displayed on the external ring to the eyepiece of the scope, for viewing by the marksman.
General & Specialized Nomenclature
In order to provide a more structured background and a system of nomenclature, we refer again to
While an exemplary conventional variable power scope 10 is used in the illustrations, fixed power (e.g., 10×, such as the M3A scope) are often used. Such fixed power scopes have the advantages of economy, simplicity, and durability, in that they eliminate at least one lens and a positional adjustment for that lens. Such a fixed power scope may be suitable for many marksmen who generally shoot at relatively consistent ranges and targets.
Variable power scopes include two focal planes. The reticle screen or glass 16 used in connection with the reticles of the present invention is preferably positioned at the first or front focal plane (“FP1”) between the distal objective lens 12 and erector lens 18, in order that the reticle thereon will change scale correspondingly with changes in magnification as the power of the scope is adjusted. This results in reticle divisions subtending the same apparent target size or angle, regardless of the magnification of the scope. In other words, a target subtending two reticle divisions at a relatively low magnification adjustment, will still subtend two reticle divisions when the power is adjusted, to a higher magnification, at a given distance from the target. This reticle location is preferred for the present system when used in combination with a variable power firearm scope.
Alternatively, reticle screen 16 may be placed at a second or rear focal plane between the zoom lens 20 and proximal eyepiece 14, if so desired. Such a second focal plane reticle will remain at the same apparent size regardless of the magnification adjustment to the scope, which has the advantage of providing a full field of view to the reticle at all times. However, the reticle divisions will not consistently subtend the same apparent target size with changes in magnification, when the reticle is positioned at the second focal plane in a variable power scope. Accordingly, it is preferred that the present system be used with first focal plane reticles in variable power scopes, due to the difficulty in using such a second focal plane reticle in a variable power scope.
The horizontal crosshair 32 and central aiming dot line 34 define a single aim point 38 at their intersection. The multiple aim point field 30 is formed of a series of horizontal rows which are seen in
Most of the horizontal rows in
In order to use the Tubb™ DTAC™ elevation and windage aim point field 30, the marksman must have a reasonably close estimate of the range to the target. This can be provided by means of the evenly spaced horizontal and vertical angular measurement stadia 31 disposed upon aim point field 30. The stadia 31 comprise a vertical row of stadia alignment markings and a horizontal row of such markings disposed along the horizontal reference line or crosshair 32. Each adjacent stadia mark, e.g. vertical marks and horizontal marks are evenly spaced from one another and subtend precisely the same angle therebetween, e.g. one mil, or a tangent of 0.001. Other angular definitions may be used as desired, e.g. the minute of angle or MOA system discussed above. The DTAC™ stadia system 31 is used by estimating some dimension of the target, or of an object close to the target. It should be noted that each of the stadia markings comprises a small triangular shape, and provides a precise, specific alignment line, to reduce errors in subtended angle estimation, and therefore in estimating the distance to the target.
It will be noted that the substantially vertical central aiming dot line 54 is skewed somewhat to the right of the true vertical reference line 56. As above, this is to compensate for gyroscopic precession or “spin drift” of a spin-stabilized bullet or projectile in its trajectory. The flying bullet's clockwise spin results in gyroscopic precession which generates a force that is transverse or normal (i.e., ninety degrees) to the arcuate trajectory, causing the bullet to deflect to the right. As above, the lateral offset or skewing of substantially vertical central aiming dot line to the right causes the user, shooter or marksman to aim or moving the alignment slightly to the left in order to position one of the aiming dots of the central line 54 on the target (assuming no windage correction).
In
Both of the reticles discussed above represent significant aids for precision shooting over long ranges, such as the ranges depicted in
The above described systems are now in use in scope reticles, but these prior art systems have been discovered to include subtle but significant errors arising from recently observed external ballistic phenomena, and the observed error has been significant (e.g., exceeding one MOA) at ranges well within the operationally significant military or police sniping range limits (e.g., 1000 yards). The prior art systems often require the marksman or shooter to bring a companion (e.g., a coach or spotter) who may be required to bring additional optics for observation and measurement and may also be required to bring along computer-like devices such as a transportable personal digital assistant (“PDA”) or a smart phone (e.g., an iPhone™ or a Blackberry™ programmed with an appropriate software application or “app”) for solving ballistics problems while in the field.
These prior art systems also require the marksman or their companion to engage in too many evaluations and calculations while in the field, and even for experienced long-range shooters, those evaluations and calculations usually take up a significant amount of time. If the marksman is engaged in military or police tactical or sniping operations, lost time when aiming may be extremely critical, (e.g., as noted in Refs 5 and 6).
None of the above cited references or patents, alone or in combination, address the combined atmospheric and ballistic problems identified by the applicant of the present invention or provide a workable and time-efficient way of developing a firing solution, while in the field. Thus, there is an unmet need for a rapid, accurate and effective rifle sight or projectile weapon aiming system and method for more precisely estimating a correct point of aim when shooting or engaging targets at long distances, especially in windy conditions.
Accordingly, it is an object of the present invention to overcome the above mentioned difficulties by providing a rapid and effective system and method for compensating for a projectile's ballistic behavior while developing a field expedient firing solution, and estimating a correct point of aim when shooting or engaging targets at long distances.
The applicant has engaged in a rigorous study of precision shooting and external ballistics and observed what initially appeared to be external ballistics anomalies when engaged in carefully controlled experiments in precise shooting at long range. The anomalies were observed to vary with environmental or atmospheric conditions, especially crosswinds. The variations in the anomalies were observed to be repeatable, and so a precise evaluation of the anomalies was undertaken and it was discovered that all of the long range reticles presently employed in the prior art systems are essentially wrong.
A refined method and aiming reticle has been developed which allows a more precise estimate of external ballistic behavior for a given projectile when a given set of environmental or atmospheric conditions are observed to be momentarily present. Expressed most plainly, the reticle of the present invention differs from prior art long range reticles in two significant and easily perceived ways:
first, the reticle and system of the present invention is configured to compensate for Crosswind Jump, and so the lateral or windage aim point adjustment axes are not horizontal, meaning that they are not simply horizontal straight lines which are perpendicular to a vertical straight line crosshair; and
second, the reticle and system of the present invention is configured to compensate for Dissimilar Wind Drift, and so the arrayed aim point indicators on each windage adjustment axis are not spaced symmetrically about the vertical crosshair, meaning that a given wind speed's full value windage offset indicator on the left side of the vertical crosshair is not spaced from the vertical crosshair at the same lateral distance as the corresponding given wind speed's full value windage offset indicator on the right side of the vertical crosshair.
Apart from the Tubb™ DTAC™ reticle discussed above, the reticles of the prior art have a vertical crosshair or post intended to be seen (through the riflescope) as being exactly perpendicular to a horizontal crosshair that is parallel to the horizon when the rifle is held level with no angular variation from vertical (or “rifle cant”). Those prior art reticles also include a plurality of “secondary horizontal crosshairs” (e.g., 24 in FIG. 2 of Sammut's U.S. Pat. No. 6,453,595). The secondary horizontal crosshairs are typically divided with evenly spaced indicia on both sides of the vertical crosshair (e.g., 26 in FIG. 2 of Sammut's U.S. Pat. No. 6,453,595 or as shown in FIG. 3 of this applicant's U.S. Pat. No. 7,325,353). These prior art reticles represent a prediction of where a bullet will strike a target, and that prior art prediction includes an assumption or estimation that a windage offset to the left is going to be identical to and symmetrical with a windage offset to the right, and that assumption is plainly, provably wrong, for reasons supported in the more arcane technical literature on ballistics and explained below.
Another assumption built into the prior art reticles pertains to the predicted effect on elevation arising from increasing windage adjustments, because the prior art reticles effectively predict that no change in elevation (i.e., holdover) should be made, no matter how much windage adjustment is needed. This second assumption is demonstrated by the fact that the prior art reticles all have straight and parallel “secondary horizontal crosshairs” (e.g., 24 in FIG. 2 of Sammut's U.S. Pat. No. 6,453,595 or as shown in FIG. 3 of this applicant's U.S. Pat. No. 7,325,353), and that assumption is also plainly, provably wrong.
The applicant of the present invention first questioned and then discarded these assumptions, choosing instead to empirically observe, record and plot the actual ballistic performance for a series of carefully controlled shots at selected ranges, and the plotted observations have been used to develop an improved method and reticle which provides a more accurate predictor of the effects of observed atmospheric and environmental conditions on a bullet's external ballistics, especially at longer ranges. The applicant's discoveries are combined into a reticle which provides easy to use and accurate estimations of the external ballistic effects of (a) spin drift, (b) crosswind jump or aeronautical jump and (c) dissimilar wind drift.
The rifle sight or projectile weapon aiming system reticle of the present invention preferably includes an array of aiming dots defining a substantially vertical crosshair and an array of lateral indicia defining a horizontal crosshair which intersect to define a central or primary aiming point. The reticle of the present invention also includes a plurality of substantially linear windage adjustment axes arrayed beneath the horizontal crosshair. The windage adjustment axes are not horizontal lines, meaning that they are not secondary horizontal crosshairs each being perpendicular to the vertical crosshair. Instead, each windage axis defines an angled or sloped array of windage offset adjustment indicia or aim points. If a windage axis line were drawn left to right through all of the windage offset adjustment indicia corresponding to a selected range (e.g., 800 yards), that windage axis line would slope downwardly from horizontal at a small angle (e.g., five degrees or greater), for a rifle barrel with right-hand twist rifling and a right-spinning projectile.
In addition, the windage offset adjustment indicia on each windage adjustment axis are not symmetrical about the vertical crosshair, meaning that selected windage offset adjustment indicator on the left side of the vertical crosshair is not spaced from the vertical crosshair at the same lateral distance as the corresponding windage offset adjustment indicator on the right side of the vertical crosshair. Instead, the reticle and method of the present invention define differing windage offsets for (a) wind from the left and (b) wind from the right. Those windage offsets refer to an elevation adjustment axis which diverges laterally from the vertical crosshair. The elevation adjustment axis defines the diverging array of elevation offset adjustment indicia for selected ranges (e.g., 300 to 1600 yards, in 100 yard increments). An elevation offset adjustment axis line could be drawn through all of the elevation offset adjustment indicia (corresponding to no wind) to define only the predicted effect of spin drift and precession, as described in this applicant's U.S. Pat. No. 7,325,353.
In accordance with the present invention, a reticle system and aiming method are provided to account for the previously ill-defined effects of the newly observed interaction between ballistic and atmospheric effects. Careful research of technical journals was used to find reports of identified effects in disparate sources, but those effects have never been addressed in a comprehensive system to provide an aiming solution or estimate which can be used by a marksman in the field.
The above and still further objects, features and advantages of the present invention will become apparent upon consideration of the following detailed description of a specific embodiment thereof, particularly when taken in conjunction with the accompanying drawings, wherein like reference numerals in the various figures are utilized to designate like components.
Referring again to
While an exemplary conventional variable power scope 10 is used in the illustrations, it will be understood that the reticle and system of the present invention may be used with other types of sighting systems or scopes in lieu of the variable power scope 10. For example, fixed power scopes are often used by many hunters and target shooters. Such fixed power scopes have the advantages of economy, simplicity, and durability, in that they eliminate at least one lens and a positional adjustment for that lens. Such a fixed power scope may be suitable for many marksmen who generally shoot at relatively consistent ranges and targets. More recently, digital electronic scopes have been developed, which operate using the same general principles as digital electronic cameras. The ballistic effect compensating reticle and aim compensation method for rifle sights or projectile weapon aiming systems of the present invention (and as set forth in the appended claims) may be employed with these other types of sighting systems or scopes, as well as with the variable power scope 10 of
While variable power scopes typically include two focal planes, the reticle screen or glass 16 used in connection with the reticles of the present invention is preferably positioned at the first or front focal plane (“FP1”) between the distal objective lens 12 and erector lens 18, in order that the reticle thereon will change scale correspondingly with changes in magnification as the power of the scope is adjusted. This results in reticle divisions subtending the same apparent target size or angle, regardless of the magnification of the scope. In other words, a target subtending two reticle divisions at a relatively low magnification adjustment, will still subtend two reticle divisions when the power is adjusted, to a higher magnification, at a given distance from the target. This reticle location is preferred for the present system when used in combination with a variable power firearm scope.
Alternatively, reticle screen 16 may be placed at a second or rear focal plane between the zoom lens 20 and proximal eyepiece 14, if so desired. Such a second focal plane reticle will remain at the same apparent size regardless of the magnification adjustment to the scope, which has the advantage of providing a full field of view to the reticle at all times. However, the reticle divisions will not consistently subtend the same apparent target size with changes in magnification, when the reticle is positioned at the second focal plane in a variable power scope. Accordingly, it is preferred that the present system be used with first focal plane reticles in variable power scopes, due to the difficulty in using such a second focal plane reticle in a variable power scope.
As noted above, the applicant's prior art DTAC™ reticles (shown in
The reticle and method of present invention as illustrated in
The reticle and method of present invention, as illustrated in
The diagrams of
As noted above, the reticles of the prior art include a vertical crosshair intended to be seen (through the riflescope) as being precisely perpendicular to a horizontal crosshair that is parallel to the horizon when the rifle is held level to the horizon with no angular variance from vertical (or “cant”). The prior art range-compensating reticles also include a plurality of “secondary horizontal crosshairs” which are typically divided with evenly spaced indicia on both sides of the vertical crosshair. These prior art range-compensating or bullet drop compensating reticles effectively represent a prediction of where a bullet will strike a target, and that prior art prediction includes an assumption that any windage aiming offset to the left (for left wind) is going to be identical to and symmetrical with a windage aiming offset to the right (for right wind). Another assumption built into the prior art reticles pertains to the predicted effect on elevation arising from increasing windage adjustments, because the prior art reticles predict that no change in elevation (i.e., holdover) should be made, no matter how much windage adjustment is needed. This second assumption is demonstrated by the fact that the prior art reticles all have straight and parallel secondary horizontal crosshairs.
The applicant of the present invention re-examined these assumptions and empirically observed, recorded and plotted the actual ballistic performance for a series of carefully controlled shots at selected ranges, and the plotted observations have been used to develop improved reticle aim point field (e.g., 150) which has been demonstrated to be a more accurate predictor of the effects of atmospheric and environmental conditions on a bullet's flight.
Experimental Approach and Prototype Development:
As noted above, reticle system 200 and the method of the present invention are useful to predict the performance of specific ammunition fired from a specific rifle system (e.g., 4), but can be used with a range of other ammunition by using pre-defined correction criteria. The data for the reticle aim point field 150 shown in
A second set of experiments conducted with a LH twist barrel (also 1:9) confirmed that the slope of the windage axes was equal magnitude but reversed when using a LH twist barrel, meaning that the windage axes rise (from right to left) at about a 5 degree angle and the substantially vertical central aiming dot line or elevation axis (illustrating the effect of spin drift) diverges to the left of a vertical crosshair (e.g., 156).
A ballistics performance calculation (using prior art methods) for a 284 Winchester cartridge loaded with a 180 Gr Sierra Match King BTHP projectile (#1980) having a ballistic coefficient of .660 when fired from a rifle providing a muzzle velocity of 2850 fps generates the data shown below, in Table 1. This data assumes a sight height of 1.5 inches above the rifle's bore and is for a temperature of 80 degrees at 2K elevation (for 4K DA) when the rifle is sighted in at 500 yards.
The reticle of the present invention preferably includes an aim point field 150 with a vertical crosshair 156 and a horizontal crosshair 152 which intersect at a right angle and also includes a plurality of windage adjustment axes (e.g., 160A) arrayed beneath horizontal crosshair 152. The windage adjustment axes (e.g., 160A) are angled downwardly at a shallow angle (e.g., five degrees, for RH twist), meaning that they are not secondary horizontal crosshairs each being perpendicular to the vertical crosshair 156. Instead, each windage axis defines an angled or sloped array of windage offset adjustment indicia (e.g., 260L-1 and 260R-1). If a windage axis line were drawn through all of the windage offset adjustment indicia corresponding to a selected range (e.g., 800 yards), that windage axis line would slope downwardly from horizontal at a small angle (e.g., five degrees), as illustrated in
As noted above, the windage offset adjustment indicia on each windage adjustment axis are not symmetrical about the vertical crosshair 156 or symmetrical around the array of elevation indicia or nearly vertical central aiming dot line 154. The nearly vertical central aiming dot line 154 provides a “no wind zero” for selected ranges (e.g., 100 to more than 1500 yards, as seen in
The phenomena or external ballistic effects observed by the applicant are not anticipated in the prior art, but applicant's research into the scientific literature has provides some interesting insights. A scientific text entitled “Rifle Accuracy Facts” by H. R. Vaughn, and at pages 195-197, describes a correlation between gyroscopic stability and wind drift. An excerpt from another scientific text entitled “Modern Exterior Ballistics” by R. L. McCoy (with appended errata published after the author's death), at pages 267-272, describes a USAF scientific inquiry into what was called “Aerodynamic Jump” due to crosswind and experiments in aircraft. Applicant's experiments have been evaluated in light of this literature and, as a result, applicant has developed a model for two external ballistics mechanisms which appear to be at work. The first mechanism is now characterized, for purposes of the system and method of the present invention, as “Crosswind Jump” wherein the elevation-hold or adjustment direction (up or down) varies, depending on whether the shooter is compensating for left crosswind (270°) or right crosswind (90°), and the present invention's adaptation to these effects is illustrated in
The second mechanism (dubbed “Dissimilar Wind Drift” for purposes of the system and method of the present invention) was observed as notably distinct lateral offsets for windage, depending on whether a cross-wind was observed as left wind (270°) or right wind (90°). Referring now to
The aiming system and method of the present invention can also be used with traditional mil-dot reticles, permitting a shooter to compensate for a projectile's ballistic behavior while developing a firing solution. This would require some time consuming calculations, but a correction factor table is illustrated in
The marksman or shooter may bring along a personal or transportable computer-like device (not shown) such as a personal digital assistant (“PDA”) or a smart phone (e.g., an iPhone™ or a Blackberry™) and that shooter's transportable computer-like device may be readily programmed with a software application (or “app”) which has been programmed with the correction factors for the shooters weapon system (e.g., using the correction factors of
Applicant's reticle system (e.g., 200 or 300) permits the shooter to express and correct the aim point selection and the firing solution in range (e.g., yards) and crosswind velocity (MPH) rather than angles (minutes of angle or MILS). Additionally the reticle aim point field (e.g., 150 or 350) provides automatic correction for spin drift, crosswind jump and dissimilar crosswind drift, none of which are provided by any other reticle. As a direct result of these unique capabilities, the shooter can develop precise long range firing solutions faster than with any other reticle. The design goal was to create a telescopic sighting system that encompasses the following attributes:
1. A system that is very quick to use and allows for shots from point blank range to well beyond 1000 yards. Time element was a huge factor in this design. Time is what wins most engagements.
2. A system that does not require an auxiliary computer or data book which takes the shooter's attention away from the target and whose failure or loss would leave the shooter stranded.
3. A system that accommodates changing atmospheric conditions, allowing its use in any reasonable geographic location.
4. A system that provides the means to actually determine target range in yards, not just measure it in MILS or MOA.
5. A system that requires fewer mathematic calculations by the user.
6. A system that uses miles per hour (mph) for windage—no MILS or MOA conversion needed (call in mph, hold in mph).
7. A system that accounts for spin drift thus giving the user a true No Wind Zero at each central aiming dot.
8. A system that accounts for crosswind jump (lift) of the bullet as it undergoes crosswind deflection.
9. A system that accounts for dissimilar wind drift (DWD) (a right-hand wind will drift a right spinning bullet further than a left-hand wind).
10. A system that allows effective elevation hold points with no external corrections under all atmospheric conditions.
11. A system that allows the user to quickly and easily adapt to changes in ammunition or rifle system velocity or ammunition ballistic (“BC”) properties by using DA correction factors which permit the user to make corrections quickly in units of distance (e.g., yards or meters) to find elevation hold points with no external corrections under all atmospheric conditions.
12. A system that allows rapid application of angle cosine range correction factors denominated in distance units (e.g., yards or meters) for rapid correction of elevation hold points under all atmospheric conditions.
Meeting these goals was accomplished by employing two concepts:
1. Providing a family of reticles which accommodate bullets with a specific ballistic coefficients (“BC”) and muzzle velocities under any atmospheric conditions.
2. Providing graphs in the reticle to facilitate most ranging and ballistic computations. This allows the user to make accurate compensations for varying shooting conditions without looking away from the scope. Graphs are powerful tools to display reference data and perform “no math” computations.
The reticle and system of the present invention can also be used with the popular M118LR .308 caliber ammunition which is typically provides a muzzle velocity of 2565 FPS. Turning now to
It will be noted that the substantially vertical central aiming dot line 354 is curved or skewed somewhat to the right of the true vertical reference line 356. As above, this is to compensate for gyroscopic precession or “spin drift” of a spin-stabilized bullet or projectile in its trajectory. The exemplary M24 or M40 variant rifle barrels have “right twist” inwardly projecting rifling which spirals to the right, or clockwise, from the proximal chamber to the distal muzzle of the barrel. The rifling imparts a corresponding clockwise stabilizing spin to the M118LR bullet (not shown). As the projectile or bullet travels an arcuate trajectory in its distal or down range ballistic flight between the muzzle and the target, the longitudinal axis of the bullet will deflect angularly to follow that arcuate trajectory. As noted above, the flying bullet's clockwise spin results in gyroscopic precession which generates a force that is transverse or normal (i.e., ninety degrees) to the arcuate trajectory, causing the bullet to deflect to the right. This effect is seen most clearly at relatively long ranges, where there is substantial arc to the trajectory of the bullet (e.g., as illustrated in
In
The nearly vertical columns 362A, 362B, 364A, 364B, etc., spread as they extend downwardly to greater and greater ranges, but not symmetrically, due to the external ballistics factors including Crosswind Jump and Dissimilar Crosswind Drift, as discussed above. These nearly vertical columns define aligned angled columns or axes of aim points configured to provide an aiming aid permitting the shooter to compensate for windage, i.e. the lateral drift of a bullet due to any crosswind component. As noted above, downrange crosswinds will have an ever greater effect upon the path of a bullet with longer ranges. Accordingly, the vertical columns spread wider, laterally, at greater ranges or distances, with the two inner columns 362A and 364A being closest to the column of central aiming dots 354 and being spaced to provide correction for a five mile per hour crosswind component, the next two adjacent columns 362B, 364B providing correction for a ten mile per hour crosswind component, etc.
In addition, a moving target must be provided with a “lead,” somewhat analogous to the lateral correction required for windage. The present scope reticle includes approximate lead indicators 366B (for slower walking speed, indicated by the “W”) and 366A (farther from the central aim point 358 for running targets, indicated by the “R”). These lead indicators 366A and 366B are approximate, with the exact lead depending upon the velocity component of the target normal to the bullet trajectory and the distance of the target from the shooter's position.
As above, in order to use the elevation and windage aim point field 350 of
Referring to
It should be noted that each of the stadia markings 402 and 404 comprises a small triangular shape, rather than a circular dot or the like, as is conventional in scope reticle markings. The polygonal stadia markings of the present system place one linear side of the polygon (preferably a relatively flat triangle) normal to the axis of the stadia markings, e.g. the horizontal crosshair 352. This provides a precise, specific alignment line, i.e. the base of the triangular mark, for alignment with the right end or the bottom of the target or adjacent object, depending upon whether the length or the height of the object is being ranged. Conventional round circles or dots are subject to different procedures by different shooters, with some shooters aligning the base or end of the object with the center of the dot, as they would with the sighting field, and others aligning the edge of the object with one side of the dot. It will be apparent that this can lead to errors in subtended angle estimation, and therefore in estimating the distance to the target.
Referring back to
Reticle 300 of
DA represents “Density Altitude” and variations in ammunition velocity can be integrated into the aim point correction method by selecting a lower or higher DA correction number, and this part of the applicant's new method is referred to as “DA Adaptability”. This means that family of reticles is readily made available for a number of different bullets. This particular example is for the USGI M118LR ammunition, which is a 0.308, 175 gr. Sierra™ Match King™ bullet, modeled for use with a rifle having scope 2.5 inches over bore centerline and a 100 yard zero. It has been discovered that the bullet's flight path will match the reticle at the following combinations of muzzle velocities and air densities:
2 k DA=2625 FPS and 43.8 MOA at 1100 yards
3 k DA=2600 FPS and 43.8 MOA at 1100 yards
4 k DA=2565 FPS and 43.6 MOA at 1100 yards
5 k DA=2550 FPS and 43.7 MOA at 1100 yards
6 k DA=2525 FPS and 43.7 MOA at 1100 yards
1100 yard come-ups were used since this bullet is still above the transonic region. Thus, the reticle's density correction graphic indicia array 500 can be used with Density Altitude Graph 550 to provide the user with a convenient method to adjust or correct the selected aim point for a given firing solution when firing using different types of ammunition or in varying atmospheric conditions with varying air densities.
In accordance with the method and system of the present invention, each user is provided with a placard or card 600 for each scope which defines the bullet path values (come-ups) at 100 yard intervals. When the user sets up their rifle system, they chronograph their rifle and pick the Density Altitude which matches rifle velocity. Handloaders have the option of loading to that velocity to match the main reticle value. These conditions which result in a bullet path that matches the reticle is referred to throughout this as the “nominal” or “main” conditions. The scope legend, viewed by zooming back to the minimum magnification, shows the model and revision number of the reticle from which can be determined the main conditions which match the reticle.
Experienced long range marksmen and persons having skill in the art of external ballistics as applied to long range precision shooting will recognize that the present invention makes available a novel ballistic effect compensating reticle system (e.g., 200 or 300) for rifle sights or projectile weapon aiming systems adapted to provide a field expedient firing solution for a selected projectile, comprising: (a) a multiple point elevation and windage aim point field (e.g., 150 or 350) including a primary aiming mark (e.g., 158 or 358) indicating a primary aiming point adapted to be sighted-in at a first selected range (e.g., 200 yards); (b) the aim point field including a nearly vertical array of secondary aiming marks (e.g., 154 or 354) spaced progressively increasing incremental distances below the primary aiming point and indicating corresponding secondary aiming points along a curving, nearly vertical axis intersecting the primary aiming mark, the secondary aiming points positioned to compensate for ballistic drop at preselected regular incremental ranges beyond the first selected range for the selected projectile having pre-defined ballistic characteristics; and (c) the aim point field also includes a first array of windage aiming marks (e.g., 260L-1 and 260 R-1) spaced apart along a secondary non-horizontal axis 160A intersecting a first selected secondary aiming point (e.g., corresponding to a selected range); (d) wherein the first array of windage aiming marks includes a first windage aiming mark spaced apart to the left of the vertical axis (260L-1) at a first windage offset distance from the vertical axis selected to compensate for right-to-left crosswind of a preselected first incremental velocity at the range of said first selected secondary aiming point, and a second windage aiming mark (260R-1) spaced apart to the right of the vertical axis at a second windage offset distance from the vertical axis selected to compensate for left-to-right crosswind of said preselected first incremental velocity at said range of said first selected secondary aiming point; (e) wherein said first array of windage aiming marks define a sloped row of windage aiming points (e.g., as best seen in
In the illustrated embodiments, the ballistic effect compensating reticle (e.g., 200 or 300) has several arrays of windage aiming marks which define a sloped row of windage aiming points having a negative slope which is a function of the right-hand spin direction for the projectile's stabilizing spin or a rifle barrel's right-hand twist rifling, thus compensating for the projectile's crosswind jump and providing a more accurate “no wind zero” for any range for which the projectile remains supersonic.
The ballistic effect compensating reticle (e.g., 200 or 300) has each secondary aiming point intersected by a secondary array of windage aiming marks (e.g., 360E) defining a sloped row of windage aiming points having a slope which is a function of the direction and velocity of said projectile's stabilizing spin or a rifle barrel's rifling twist rate and direction, and that sloped row of windage aiming points are spaced for facilitating aiming compensation for ballistics and windage for two or more preselected incremental crosswind velocities (e.g., 5, 10, 15, 20 and 25 mph), at the range of the corresponding secondary aiming point (e.g., 300 yards for windage aiming mark array 360E). In the illustrated embodiment, each sloped row of windage aiming points includes windage aiming marks positioned to compensate for leftward and rightward crosswinds of 10 miles per hour and 20 miles per hour at the range of the secondary aiming point corresponding to said sloped row of windage aiming points, and at least one of the sloped row of windage aiming points is bounded by laterally spaced distance indicators. Preferably, at least one of the windage aiming points is proximate an air density or projectile ballistic characteristic adjustment indicator such as those arrayed in density correction indicia array 500, and the air density or projectile ballistic characteristic adjustment indicator is preferably a Density Altitude (DA) correction indicator.
Generally, the ballistic effect compensating reticle (e.g., 200 or 300) defines a nearly vertical array of secondary aiming marks (e.g., 154 or 354) indicating corresponding secondary aiming points along a curving, nearly vertical axis are curved in a direction that is a function of the direction of said projectile's stabilizing spin or a rifle barrel's rifling direction, thus compensating for spin drift. The primary aiming mark (e.g., 358) is formed by an intersection of a primary horizontal sight line (e.g., 352) and the nearly vertical array of secondary aiming marks indicating corresponding secondary aiming points along the curving, nearly vertical axis. The primary horizontal sight line includes preferably a bold, widened portion (370L and 370R) located radially outward from the primary aiming point, the widened portion having an innermost pointed end located proximal of the primary aiming point. The ballistic effect compensating reticle preferably also has a set of windage aiming marks spaced apart along the primary horizontal sight line 352 to the left and right of the primary aiming point to compensate for target speeds corresponding to selected leftward and rightward velocities, at the first selected range.
Ballistic effect compensating reticle aim point field (e.g., 150 or 350) preferably also includes a second array of windage aiming marks spaced apart along a second non-horizontal axis intersecting a second selected secondary aiming point; and the second array of windage aiming marks includes a third windage aiming mark spaced apart to the left of the vertical axis at a third windage offset distance from the vertical axis selected to compensate for right-to-left crosswind of the preselected first incremental velocity (e.g., 10 mph) at the range of said second selected secondary aiming point (e.g., 800 yards), and a fourth windage aiming mark spaced apart to the right of the vertical axis at a fourth windage offset distance from the vertical axis selected to compensate for left-to-right crosswind of the same preselected first incremental velocity at the same range, and the second array of windage aiming marks define another sloped row of windage aiming points having a slope which is also a function of the direction and velocity of said projectile's stabilizing spin or a rifle barrel's rifling twist rate and direction, thus compensating for the projectile's crosswind jump. In addition, the ballistic effect compensating reticle's aim point field also includes a third array of windage aiming marks spaced apart along a third non-horizontal axis intersecting a third selected secondary aiming point, where the third array of windage aiming marks includes a fifth windage aiming mark spaced apart to the left of the vertical axis at a fifth windage offset distance from the vertical axis selected to compensate for right-to-left crosswind of the preselected first incremental velocity at the range of said third selected secondary aiming point, and a sixth windage aiming mark spaced apart to the right of the vertical axis at a sixth windage offset distance from the vertical axis selected to compensate for left-to-right crosswind of said preselected first incremental velocity at said range of said third selected secondary aiming point; herein said second array of windage aiming marks define another sloped row of windage aiming points having a slope which is also a function of the direction and velocity of said projectile's stabilizing spin or a rifle barrel's rifling twist rate and direction, thus compensating for crosswind jump.
The ballistic effect compensating reticle (e.g., 200 or 300) may also have the aim point field's first array of windage aiming marks spaced apart along the second non-horizontal axis to include a third windage aiming mark spaced apart to the left of the vertical axis at a third windage offset distance from the first windage aiming mark selected to compensate for right-to-left crosswind of twice the preselected first incremental velocity at the range of said second selected secondary aiming point, and have a fourth windage aiming mark spaced apart to the right of the vertical axis at a fourth windage offset distance from the second windage aiming mark selected to compensate for left-to-right crosswind of twice said preselected first incremental velocity at said range of said selected secondary aiming point. Thus the third windage offset distance is greater than or lesser than the fourth windage offset distance, where the windage offset distances are a function of or are determined by the direction and velocity of the projectile's stabilizing spin or a rifle barrel's rifling twist rate and direction, thus compensating for the projectile's Dissimilar Wind Drift. The ballistic effect compensating reticle has the third windage offset distance configured to be greater than the fourth windage offset distance, and the windage offset distances are a function of or are determined by the projectile's right hand stabilizing spin or a rifle barrel's rifling right-twist direction, thus compensating for said projectile's Dissimilar Wind Drift.
Broadly speaking, the ballistic effect compensating reticle system (e.g., 200 or 300) has an aim point field configured to compensate for the selected projectile's ballistic behavior while developing a field expedient firing solution expressed two-dimensional terms of:
(a) range or distance, used to orient a field expedient aim point vertically among the secondary aiming marks in said vertical array, and
(b) windage or relative velocity, used to orient said aim point laterally among a selected array of windage hold points.
The ballistic effect aim compensation method for use when firing a selected projectile from a selected rifle or projectile weapon (e.g., 4) and developing a field expedient firing solution, comprises: (a) providing a ballistic effect compensating reticle system (e.g., 200 or 300) comprising a multiple point elevation and windage aim point field (e.g., 150 or 350) including a primary aiming mark intersecting a nearly vertical array of secondary aiming marks spaced along a curving, nearly vertical axis, the secondary aiming points positioned to compensate for ballistic drop at preselected regular incremental ranges beyond the first selected range for the selected projectile having pre-defined ballistic characteristics; and said aim point field also including a first array of windage aiming marks spaced apart along a secondary non-horizontal axis intersecting a first selected secondary aiming point; wherein said first array of windage aiming marks define a sloped row of windage aiming points having a slope which is a function of the direction and velocity of said projectile's stabilizing spin or a rifle barrel's rifling twist rate and direction, thus compensating for said projectile's crosswind jump; (b) based on at least the selected projectile, identifying said projectile's associated nominal Air Density ballistic characteristics; (c) determining a range to a target, based on the range to the target and the nominal air density ballistic characteristics of the selected projectile, determining a yardage equivalent aiming adjustment for the projectile weapon; (d) determining a windage hold point, based on any crosswind sensed or perceived, and (e) aiming the rifle or projectile weapon using said yardage equivalent aiming adjustment for elevation hold-off and said windage hold point.
The ballistic effect aim compensation method of the present invention includes providing ballistic compensation information as a function of and indexed according to an atmospheric condition such as density altitude for presentation to a user of a firearm, and then associating said ballistic compensation information with a firearm scope reticle feature to enable a user to compensate for existing density altitude levels to select one or more aiming points displayed on the firearm scope reticle (e.g., 200 or 300). The ballistic compensation information is preferably encoded into markings (e.g., indicia array 500) disposed on the reticle of the scope via an encoding scheme, and the ballistic compensation information is preferably graphed, or tabulated into markings disposed on the reticle of the scope. In the illustrated embodiments, the ballistic compensation information comprises density altitude determination data and a ballistic correction chart indexed by density altitude.
The ballistic effect aim compensation system to adjust the point of aim of a projectile firing weapon or instrument firing a selected projectile under varying atmospheric and wind conditions (e.g. with a reticle such as 200 or 300) includes a plurality of aiming points disposed upon said reticle, said plurality of aiming points positioned for proper aim at various predetermined range-distances and wind conditions and including at least a first array of windage aiming marks spaced apart along a non-horizontal axis (e.g., array 360-0 for 800 yards), wherein said first array of windage aiming marks define a sloped row of windage aiming points having a slope which is a function of the direction and velocity of the selected projectile's stabilizing spin or a rifle barrel's rifling twist rate and direction, thus compensating for said selected projectile's crosswind jump; and where all of said predetermined range-distances and wind conditions are based upon a baseline atmospheric condition. The system preferably includes a means for determining existing density altitude characteristics (such as DA graph 550) either disposed on the reticle or external to the reticle; and also includes ballistic compensation information indexed by density altitude criteria configured to be provided to a user or marksman such that the user can compensate or adjust an aim point to account for an atmospheric difference between the baseline atmospheric condition and an actual atmospheric condition; wherein the ballistic compensation information is based on and indexed according to density altitude to characterize the actual atmospheric condition.
Preferably, the ballistic compensation information is encoded into the plurality of aiming points disposed upon the reticle, as in
Having described preferred embodiments of a new and improved reticle and method, it is believed that other modifications, variations and changes will be suggested to those skilled in the art in view of the teachings set forth herein. It is therefore to be understood that all such variations, modifications and changes are believed to fall within the scope of the present invention as set forth in the following claims.
This application claims priority to and is related to: (1) commonly owned U.S. provisional patent application No. 61/429,128, filed Jan. 1, 2011, and (2) commonly owned U.S. provisional patent application No. 61/437,990, filed Jan. 31, 2011 and (3) commonly owned and copending U.S. patent application Ser. No. 13/342,197, filed Jan. 2, 2012, the entire disclosures of which are incorporated herein by reference. This application is a Divisional application for copending, allowed U.S. patent application Ser. No. 13/342,197.
Number | Name | Date | Kind |
---|---|---|---|
197397 | O'Neil | Nov 1877 | A |
252240 | Morris | Jan 1882 | A |
D14355 | Dressel | Oct 1883 | S |
912050 | Wanee | Feb 1909 | A |
1006699 | Straubel | Oct 1911 | A |
1107163 | Grauheding | Aug 1914 | A |
1127230 | Grauheding | Feb 1915 | A |
1190121 | Critchett | Jul 1916 | A |
1406620 | Dear | Feb 1922 | A |
1425321 | Etherington | Aug 1922 | A |
1428389 | Miller | Sep 1922 | A |
1540772 | Gibbs | Jun 1925 | A |
1851189 | King | Mar 1932 | A |
2090930 | Schaffner | Aug 1937 | A |
2094623 | Stokey | Oct 1937 | A |
2150629 | Mossberg | Mar 1939 | A |
2154454 | Joyce | Apr 1939 | A |
2171571 | Karnes | Sep 1939 | A |
2417451 | Schaffner | Mar 1947 | A |
2420273 | West | May 1947 | A |
2450712 | Brown | Oct 1948 | A |
2464521 | McCall | Mar 1949 | A |
2486940 | Garber et al. | Nov 1949 | A |
2615252 | Wing | Oct 1952 | A |
2806287 | Sullivan | Sep 1957 | A |
2807981 | Barnes | Oct 1957 | A |
2823457 | Mihalyi | Feb 1958 | A |
2891445 | Staubach | Jun 1959 | A |
2949816 | Weaver | Aug 1960 | A |
2955512 | Kollmorgen et al. | Oct 1960 | A |
3058391 | Leupold | Oct 1962 | A |
3190003 | O'Brien | Jun 1965 | A |
3229370 | Plisk et al. | Jan 1966 | A |
3297389 | Gibson | Jan 1967 | A |
3313026 | Akin, Jr. | Apr 1967 | A |
3381380 | Thomas | May 1968 | A |
D211467 | Wilbur | Jun 1968 | S |
3392450 | Herter et al. | Jul 1968 | A |
3410644 | McLendon | Nov 1968 | A |
3431652 | Leatherwood | Mar 1969 | A |
3470616 | Thompson | Oct 1969 | A |
3492733 | Leatherwood | Feb 1970 | A |
3540256 | Thompson | Nov 1970 | A |
3575085 | McAdam, Jr. | Apr 1971 | A |
3682552 | Hartman | Aug 1972 | A |
3684376 | Lessard | Aug 1972 | A |
3743818 | Marasco et al. | Jul 1973 | A |
3744133 | Fukushima et al. | Jul 1973 | A |
3744143 | Kilpatrick | Jul 1973 | A |
3749494 | Hodges | Jul 1973 | A |
3777404 | Oreck | Dec 1973 | A |
3782822 | Spence | Jan 1974 | A |
3798796 | Stauff et al. | Mar 1974 | A |
3826012 | Pachmayr | Jul 1974 | A |
3876304 | Novak | Apr 1975 | A |
3902251 | Ross | Sep 1975 | A |
3948587 | Rubbert | Apr 1976 | A |
4014482 | Esker et al. | Mar 1977 | A |
4102053 | Colwell | Jul 1978 | A |
4132000 | Dulude | Jan 1979 | A |
4244586 | Gorrow | Jan 1981 | A |
4247161 | Unertl, Jr. | Jan 1981 | A |
4248496 | Akin, Jr. et al. | Feb 1981 | A |
4255013 | Allen | Mar 1981 | A |
4263719 | Murdoch | Apr 1981 | A |
4285137 | Jennie | Aug 1981 | A |
4389791 | Ackerman | Jun 1983 | A |
4395096 | Gibson | Jul 1983 | A |
4403421 | Shepherd | Sep 1983 | A |
4408842 | Gibson | Oct 1983 | A |
4458436 | Bohl | Jul 1984 | A |
4497548 | Burris | Feb 1985 | A |
4531052 | Moore | Jul 1985 | A |
4561204 | Binion | Dec 1985 | A |
4584776 | Shepherd | Apr 1986 | A |
4616421 | Forsen | Oct 1986 | A |
4618221 | Thomas | Oct 1986 | A |
4627171 | Dudney | Dec 1986 | A |
D288465 | Darnall et al. | Feb 1987 | S |
4671165 | Heidmann et al. | Jun 1987 | A |
4695161 | Reed | Sep 1987 | A |
4777352 | Moore | Oct 1988 | A |
4787739 | Gregory | Nov 1988 | A |
4806007 | Bindon | Feb 1989 | A |
H613 | Stello et al. | Apr 1989 | H |
4833786 | Shores, Sr. | May 1989 | A |
D306173 | Reese | Feb 1990 | S |
4912853 | McDonnell et al. | Apr 1990 | A |
4949089 | Ruszkowski, Jr. | Aug 1990 | A |
4957357 | Barns et al. | Sep 1990 | A |
4965439 | Moore | Oct 1990 | A |
5026158 | Golubic | Jun 1991 | A |
5157839 | Beutler | Oct 1992 | A |
5171933 | Eldering | Dec 1992 | A |
5181323 | Cooper | Jan 1993 | A |
5181719 | Cleveland, III | Jan 1993 | A |
5194908 | Lougheed et al. | Mar 1993 | A |
5223560 | Cipolli et al. | Jun 1993 | A |
5223650 | Finn | Jun 1993 | A |
5375072 | Cohen | Dec 1994 | A |
5415415 | Mujic | May 1995 | A |
5454168 | Langner | Oct 1995 | A |
5469414 | Okamura | Nov 1995 | A |
5491546 | Wascher et al. | Feb 1996 | A |
5616903 | Springer | Apr 1997 | A |
5631654 | Karr | May 1997 | A |
5657571 | Peterson | Aug 1997 | A |
5672840 | Sage et al. | Sep 1997 | A |
5781505 | Rowland | Jul 1998 | A |
D397704 | Reese | Sep 1998 | S |
D403686 | Reese | Jan 1999 | S |
5860655 | Starrett | Jan 1999 | A |
5887352 | Kim | Mar 1999 | A |
5920995 | Sammut | Jul 1999 | A |
5960576 | Robinson | Oct 1999 | A |
6025908 | Houde-Walter | Feb 2000 | A |
6032374 | Sammut | Mar 2000 | A |
6041508 | David | Mar 2000 | A |
6049987 | Robell | Apr 2000 | A |
6058921 | Lawrence et al. | May 2000 | A |
6064196 | Oberlin et al. | May 2000 | A |
6213470 | Miller | Apr 2001 | B1 |
6252706 | Kaladgew | Jun 2001 | B1 |
6269581 | Groh | Aug 2001 | B1 |
6357158 | Smith, III | Mar 2002 | B1 |
D455811 | Fedio, Jr. | Apr 2002 | S |
D456057 | Smith, III | Apr 2002 | S |
6453595 | Sammut | Sep 2002 | B1 |
6516551 | Gaber | Feb 2003 | B2 |
6516699 | Sammut et al. | Feb 2003 | B2 |
6568092 | Brien | May 2003 | B1 |
D475758 | Ishikawa | Jun 2003 | S |
6574900 | Malley | Jun 2003 | B1 |
6591537 | Smith | Jul 2003 | B2 |
6681512 | Sammut | Jan 2004 | B2 |
6729062 | Thomas et al. | May 2004 | B2 |
6772550 | Leatherwood | Aug 2004 | B1 |
6813025 | Edwards | Nov 2004 | B2 |
6862832 | Barrett | Mar 2005 | B2 |
6886287 | Bell et al. | May 2005 | B1 |
D506520 | Timm et al. | Jun 2005 | S |
D517153 | Timm et al. | Mar 2006 | S |
D536762 | Timm et al. | Feb 2007 | S |
7171776 | Staley, III | Feb 2007 | B2 |
7185455 | Zaderey | Mar 2007 | B2 |
7325353 | Cole et al. | Feb 2008 | B2 |
7603804 | Zaderey et al. | Oct 2009 | B2 |
7712225 | Sammut | May 2010 | B2 |
7748155 | Cole | Jul 2010 | B2 |
7832137 | Sammut | Nov 2010 | B2 |
20020124452 | Sammut | Sep 2002 | A1 |
20020129535 | Osborn, II | Sep 2002 | A1 |
20040016168 | Thomas et al. | Jan 2004 | A1 |
20040020099 | Osborn, II | Feb 2004 | A1 |
20040088898 | Barrett | May 2004 | A1 |
20050005495 | Smith | Jan 2005 | A1 |
20050021282 | Sammut et al. | Jan 2005 | A1 |
20050229468 | Zaderey et al. | Oct 2005 | A1 |
20050257414 | Zaderey et al. | Nov 2005 | A1 |
20060260171 | Cole et al. | Nov 2006 | A1 |
20070044364 | Sammut et al. | Mar 2007 | A1 |
20080061509 | Potterfield | Mar 2008 | A1 |
20080098640 | Sammut et al. | May 2008 | A1 |
20090199451 | Zaderey et al. | Aug 2009 | A1 |
20100038854 | Mraz | Feb 2010 | A1 |
Number | Date | Country |
---|---|---|
3401855 | Jul 1985 | DE |
3834924 | Apr 1990 | DE |
20008101 | Sep 2000 | DE |
2094950 | Sep 1982 | GB |
2294133 | Apr 1996 | GB |
55-036823 | Mar 1980 | JP |
9601404 | Jan 1996 | WO |
9737193 | Oct 1997 | WO |
02103274 | Dec 2002 | WO |
Entry |
---|
Aerodynamic Jump Caused by the Wind, http://bisonballistics.com/system/uploaded—files/9/original/aerodynamic—jump—target.png, Bison Ballistics, printed Dec. 30, 2011. |
Chung, Gregory K. W. K., Nagashima, Sam O., Delacruz, Girlie C., Lee, John J., Wainess, Richard and Baker, Eva L., Review of Rifle Marksmanship Training Research, Cresst Report 783, The National Center for Research on Evaluation, Standards, and Student Testing, Jan. 2011. |
Johnson, Richard F., Statistical Measures of Marksmanship, USARIEM Technical Note TN-01/2, U.S. Army Research Institute of Environmental Medicine, Feb. 2001. |
Military Handbook: Range Facilities and Miscellaneous Training Facilities Other than Buildings, http://www.everyspec.com, MIL-HDBK-1027/3A, Jan. 31, 1989. |
Military Specification: Propellants for Small Arms Ammunition, http://www.everyspec.com, MIL-P-3984J Amendment 3, Jun. 12, 2000. |
Military Specification: Rifle, 7.62MM, Sniper w/Day Optical Sight and Carrying Cases, M24, http://www.everyspec.com, MIL-R-71126 (AR), Sep. 24, 1992. |
Northwinds Flags, RFC-USBR Windrose, https://sites.google.com/a/wildblue.net/northwind-flags/home/Wind-Rose-2.jpg, printed Dec. 30, 2011. |
Performance Specification: Rifle, 7.62MM; Semi-Automatic Sniper System (SASS)—M110, MIL-PRF-32316 (W/ Amendment 1), Oct. 5, 2009. |
Rifle Marksmanship M16A1, M16A2/3, M16A4, and M4 Carbine, C 4, FM 3-22.9, Department of the Army, Sep. 13, 2006. |
Von Wahlde, Raymond & Metz, Dennis, Sniper Weapon Fire Control Error Budget Analysis, US Army ARL-TR-2065, Aug. 1999—arl.army.mil. |
“http://www.aircav.com/cobra/ballistic.html”, printed Dec. 30, 2011, discussion of ballistics, interior, exterior, aerial, terminal and dispersion. |
“http://www.hnsa.org/doc/firecontrol/partc.htm”, printed Dec. 30, 2011, discussion of the projectile in flight-exterior ballistics. |
Jonathan M. Weaver, Jr., LTC, USA Ret., Infantry, System Error Budgets, Target Distributions and Hitting Performance Estimates for General-Purpose Rifles and Sniper Rifles of 7.62x51mm and Larger Calibers, AD-A228 398, TR-461, AMSAA, May 1990. |
Kent, R.H. and E.J. McShane, An Elementary Treatment of the Motion of a Spinning Projectile About it's Center of Gravity, Aberdeen Proving Grounds (“APG”), MD, BRL Memorandum Report No. 85, Apr. 1944. |
Leupold® America's Optics Authority®: Ballistics Aiming System®. |
Leupold® Tactical Optics: Using the Tactical Reticle System—Mil Dot/TMR®/SPR®/CM-R2™ Usage Instructions. |
Leupold®: Ballistics Reticle Supplement. |
US Army FM-23-10, Sniper Training, United States Army Infantry School ATSH-IN-S3, Fort Benning, GA 31905-5596, Aug. 1994. |
USMC MCWP 3-15.3 (formerly FMFM 1-3B), Sniping, PCN 143 000118 00, Doctrine Division (C42) US Marine Corps Combat Development Command, 2 Broadway Street Suite 210 Quantico, VA 22134-5021, May 2004. |
Number | Date | Country | |
---|---|---|---|
20160252324 A1 | Sep 2016 | US |
Number | Date | Country | |
---|---|---|---|
61429128 | Jan 2011 | US | |
61437990 | Jan 2011 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13342197 | Jan 2012 | US |
Child | 14216674 | US |