BALLISTIC RANGE COMPENSATION FOR PROJECTILE WEAPON AIMING BASED ON AMMUNITION CLASSIFICATION

Abstract

A reticle of a projectile weapon aiming system such as a riflescope includes a primary aiming mark adapted to be sighted-in at a first selected range and further includes a plurality of secondary aiming marks spaced apart below the primary aiming mark. The secondary aiming marks are positioned to compensate for ballistic drop at preselected incremental ranges beyond the first selected range, for a selected group of ammunition having similar ballistic characteristics. Angles subtended by adjacent aiming marks of the reticle can be adjusted by changing the optical power of the riflescope, to thereby compensate for ballistic characteristics of different ammunition. In some embodiments, the reticle includes a set of windage aiming marks spaced apart along at least one secondary horizontal axis intersecting a selected one of the secondary aiming marks, to facilitate compensation for the effect of crosswinds on the trajectory of the projectile.

Description

TECHNICAL FIELD

This application relates to projectile weapon aiming systems such as riflescopes, to reticle configurations for projectile weapon aiming systems, and to associated methods of compensating for ballistic characteristics.

BACKGROUND OF THE INVENTION

Projectile weapon aiming systems are discussed herein principally with reference to their use on rifles and embodied in telescopic sights commonly known as riflescopes. It will become apparent, however, that projectile weapon aiming systems may include aiming devices other than riflescopes, and may be used on weapons other than rifles, which are capable of propelling projectiles along substantially predeterminable trajectories, e.g., handguns, crossbows, and artillery.

A factor that must be taken into account in long-range shooting is the curved trajectory traversed by a bullet or other projectile as it falls from its initial trajectory while traveling the distance from the gun to the target, i.e., “range.” An aiming line of sight emanating from a reticle aiming mark of a riflescope rigidly affixed to the gun is straight, and hence the line of sight can intersect the curved trajectory only at a discrete range. At other ranges the projectile will pass below or above the aiming line of sight, necessitating the use of elevation adjustments for aiming. Elevation adjustments in such riflescopes are typically made by turning an adjustment mechanism of the riflescope to impart vertical movement of optical elements (as described, for example, in U.S. Pat. No. 3,297,389 of Gibson) or of the reticle (as described, for example, in U.S. Pat. No. 3,058,391 of Leupold), so that the aiming line of sight is accurately “sighted-in” at the range of the target. To adjust for the effect of crosswinds, riflescopes also typically include a separate adjustment mechanism for imparting horizontal movement to the optical elements or reticle. In yet other projectile weapon aiming systems, the entire aiming device is adjusted relative to the weapon via an adjustable sight mount. Adjustment of the elevation and windage is time consuming and may require the shooter to take his or her eyes off the target while manipulating the adjustment mechanisms.

There have been proposed numerous reticles and riflescopes designed to provide the shooter with a plurality of aiming marks for shooting at targets at various predetermined ranges, i.e., aiming marks producing line of sight/trajectory intersections at various ranges. Some of these include devices for approximating the range to the target. These riflescopes propose to eliminate the need to make elevation adjustments in the riflescope to compensate for bullet drop at different ranges. Exemplary riflescopes are disclosed in U.S. Pat. Nos. 3,190,003 of O'Brien; 1,190,121 of Critchett; 3,392,450 of Herter et al.; 3,431,652 of Leatherwood; 3,492,733 of Leatherwood; 6,032,374 of Sammut; and 6,591,537 of Smith. Most of these patents propose riflescopes providing a plurality of range-related aiming marks accompanied with aiming mark selection devices, the use of which depends on relative height of the image of a target of known or estimable height compared to the height of a feature in the reticle.

Using modern laser rangefinders and other ranging techniques, it is now possible to quickly determine a range to target more accurately than by using one of the range-finding reticles described above.

U.S. Pat. No. 3,948,587 of Rubbert proposes a riflescope with a reticle that includes vertically adjacent target-spanning and aiming apertures dimensioned so that when a target of known or estimable size is framed in one of the apertures, the gun is thereby aimed for the correct range to the target. However, Rubbert does not provide an aiming mark or points of reference when the target is at a range such that it does not fit any of the apertures. The apparent spacing of the target-spanning and aiming apertures can be changed by varying the optical power of the riflescope; however, due to a limited amount of optical power adjustment available, the riflescope of Rubbert is useful only for aiming at targets within a limited size range. For example, Rubbert describes a riflescope that can be adjusted for use in aiming at targets sized between 14 and 40 inches in height. Attempting to fit smaller or larger targets in the apertures would result in gross aiming errors.

U.S. Pat. Nos. 6,032,374 of Sammut and 6,591,537 of Smith propose reticles having a series of secondary aiming marks spaced below a primary aiming mark at predetermined intervals for compensating for bullet drop. After determining or estimating an observed range, the shooter selects the secondary aiming mark most closely corresponding to the observed range. The secondary aiming marks of Sammut are evenly spaced, but a bullet's trajectory is parabolic, so Sammut requires preliminary collection of ballistic data to determine the range corresponding to each secondary aiming mark. The corresponding ranges determined by the collection of ballistic data are applicable only for the ballistics of particular ammunition for which data is collected. Furthermore, a shooter must either memorize the ranges that are empirically determined or refer to a worksheet where the ballistic data and corresponding ranges have been recorded.

Smith purports to provide secondary aiming marks for regular incremental ranges (typically 300, 400, 500, and 600 yards) in an attempt to eliminate the need, as with the device of Sammut, to refer to ballistics data or to memorize the ranges corresponding to the secondary aiming marks. However, the ranges of the secondary aiming marks of Smith are accurate only for a particular predetermined rifle and ammunition combination, referred to as the ballistic “factor.” For ammunition having a ballistic factor different from the factor for which the reticle is designed, Smith proposes to apply a decal to the stock of the rifle or some other convenient location for reference in determining the irregular ranges at which the secondary aiming marks can be used to aim the rifle.

The present inventors have recognized a need for an improved projectile weapon aiming system for accurately compensating for ballistic drop and windage for a variety of ammunition having different ballistic characteristics.

SUMMARY OF THE INVENTION

In accordance with preferred embodiments, a reticle for use in a projectile weapon aiming system includes a primary aiming mark adapted to be sighted-in at a first selected range and two or more secondary aiming marks spaced apart below the primary aiming mark along a vertical axis intersecting the primary aiming mark. The secondary aiming marks are positioned to compensate for ballistic drop at preselected incremental ranges beyond the first selected range for a selected group of ammunition having similar ballistic characteristics.

The reticle is preferably located proximate a rear focal plane of a riflescope, between a power-varying erector lens assembly and an ocular of the riflescope, so that angles subtended by adjacent aiming marks of the reticle can be adjusted by changing the optical power of the riflescope, to thereby compensate for ballistic characteristics of different ammunition and firing velocities. A set of fiducial marks may be associated with a power selector mechanism of the riflescope for prescribing at least two different optical power settings corresponding to at least two different groups of ammunition. Each of the fiducial marks indicates an optical power setting at which the secondary aiming marks accurately compensate for ballistic drop for a selected group of ammunition at the preselected incremental ranges. Preferably, the groups of ammunition are chosen based on empirical data, to group together ammunition having ballistic drop at the incremental ranges of the secondary aiming marks that is within an acceptable error tolerance of a mean ballistic drop of the group.

In some embodiments, the reticle includes a set of windage aiming marks spaced apart along at least one secondary horizontal axis intersecting a selected one of the secondary aiming marks, to facilitate compensation in aiming for the effect of crosswinds on the trajectory of the projectile.

Methods of aiming are also disclosed, in which the optical power of the riflescope is first adjusted until it corresponds to the ballistic characteristics of the selected ammunition. Thereafter, an observed range to target is determined, for example, by estimation or use of a range-finding device, before aiming with the secondary aiming mark that most closely corresponds to the observed range. In windy conditions, one of the windage aiming marks associated with the selected secondary aiming mark can be chosen based on an observed crosswind velocity, to compensate for crosswind effects at the observed range.

Additional aspects and advantages of this invention will be apparent from the following detailed description of preferred embodiments, which proceeds with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side elevation view of a riflescope mounted on a rifle in accordance with a preferred embodiment;

FIG. 2 is a schematic diagram showing optical elements of a riflescope in accordance with a preferred embodiment;

FIG. 3 is a view of a reticle in accordance with a preferred embodiment as viewed through an ocular (eyepiece) of a riflescope;

FIG. 4 is a view of the reticle of FIG. 3 including dimension lines and reference numerals referred to in the detailed description for describing the various features of the reticle;

FIG. 5 is a view of a reticle in accordance with a second preferred embodiment, which is adapted for big game hunting;

FIG. 6 is a view of a reticle in accordance with a third preferred embodiment, also adapted for big game hunting;

FIG. 7 is an enlarged top view of the riflescope of FIG. 1, showing detail of a power selector mechanism and associated fiducials used for varying the optical power setting of the riflescope to compensate for ballistic differences between two groups of ammunition; and further showing associated ranging fiducials used, in cooperation with ranging features of the reticle and the power selector mechanism, to estimate the range to a target of known or estimable size;

FIG. 8 is a table listing ballistic drop data for a variety of ammunition at selected incremental ranges corresponding to secondary aiming marks of the reticle of FIG. 5; the ammunition is grouped into two groups corresponding to two different optical power settings of the riflescope of FIG. 7, which are selected to compensate for ballistic characteristics of the two groups of ammunition;

FIG. 9 is a view of the reticle of FIG. 5 showing range-estimating features of the reticle being used to determine an estimated range to a game animal of known or estimated size; and

FIG. 10 is a view of the reticle of FIG. 3 shown aimed at a varmint at a known or estimated range of 400 yards and compensating for a known or estimated leftward (right-to-left) crosswind of 20 miles per hour.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Throughout the specification, reference to “one embodiment,” “an embodiment,” or “some embodiments” means that a particular described feature, structure, or characteristic is included in at least one embodiment. Thus appearances of the phrases “in one embodiment,” “in an embodiment,” or “in some embodiments” in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the described features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

Furthermore, the described features, structures, characteristics, and methods may be combined in any suitable manner in one or more embodiments. Those skilled in the art will recognize that the various embodiments can be practiced without one or more of the specific details or with other methods, components, materials, etc. In other instances, well-known structures, materials, or operations are not shown or not described in detail to avoid obscuring aspects of the embodiments.

FIG. 1 is a side elevation view of a riflescope 10 mounted to a rifle 14 in accordance with a preferred embodiment. FIG. 2 is a schematic diagram showing an arrangement of optical elements 16 of riflescope 10, together with ray trace lines 18 indicating the path of light from an observed object (not shown) located to the left of the assembly of optical elements 16, as the light travels through the optical system along an optical path. With reference to FIGS. 1 and 2, riflescope 10 includes a tubular housing 20 that supports at opposite ends an objective or objective lens assembly 22 and an ocular or ocular lens assembly 26 (sometimes referred to as an eyepiece or eyepiece lens assembly). Objective 22 focuses the image of an observed object at a first (front) focal plane 28 located medially of objective 22 and ocular 26. A power-adjusting erector lens assembly 30 interposed between objective 22 and ocular 26 inverts the image and refocuses it at a second (rear) focal plane 32 between erector lens assembly 30 and ocular 26. A preferred riflescope 10 may comprise, for example, a VARI-X® III brand riflescope sold by Leupold & Stevens, Inc., Beaverton, Oreg., USA, modified according to various preferred embodiments to include a reticle 40 of the kind described below. At least a part of erector lens assembly 30 is movable in response to rotation of a power selector ring 34 or other power selector mechanism to adjust the optical power of riflescope 10 within a predetermined range of magnification. For example, the optical power of riflescope 10 may range between approximately 8.5× and 25× magnification, in accordance with a first preferred embodiment, or between approximately 6.5× and 20× magnification, in accordance with an alternative embodiment. Other embodiments may allow optical power adjustment within different ranges of adjustment, such as 4.5-14×, 3.5-10×, and 2.5-8×, for example, the optical zoom ratio in each instance being approximately 3:1. In yet other embodiments, the optical power of riflescope 10 may be fixed.

Reticle 40 is located in the optical path between objective 22 and ocular 26 and more preferably between erector lens assembly 30 and ocular 26, at or adjacent second focal plane 32. By way of example, reticle 40 may be used in a riflescope 10 in a configuration of certain riflescopes sold by Leupold & Stevens, Inc., Beaverton, Oreg., USA under the trademarks LPS®, VARI-X®, VX®, and others. However, the reticles described herein are not limited to use in riflescopes or with rifles, but may also be used in various other types of sighting devices and projectile weapon aiming devices and may be used to aim one or more of a variety of projectile weapons, such as rifles, pistols, crossbows, artillery, and others.

FIG. 3 is an enlarged pictorial representation of reticle 40 as viewed through ocular 26 of riflescope 10. FIG. 4 is another enlarged pictorial view of reticle 40, with reference numbers and dimension lines, as referred to below. Reticle 40 is preferably formed on a substantially flat disc of optical quality material, such as glass or plastic, and includes a primary aiming mark 50 (also referred to herein as the primary aiming point 50) formed by the intersection of a primary horizontal sight line 52 and a primary vertical sight line 54. While primary sight lines 52 and 54 and other indicia, described below, may be marked on the surface of a transparent reticle disc, they may also be embodied in other forms, such as reticle wires, iron sights, illuminated reticle devices, projected targeting displays, head-up displays, simulated reticle images, and the like. Thus, the terms “reticle”, “mark”, “marking”, “marks”, “lines”, and the like are not limited to permanent inscriptions on a physical object, but are intended to also include all kinds of visually perceptible patterns, signs, and symbols, regardless of the way in which they are created and regardless of whether their elements are permanent or transitory in nature, or a combination of both permanent and transitory elements.

The arrangement and selection of the aiming marks of reticle 40 of FIG. 3 are particularly suited to varmint shooting, in which the targeted animals are relatively small, the optical power range of riflescope 10 is relatively high, and small fast ammunition is used. FIGS. 5 and 6 are enlarged pictorial views of second and third reticle embodiments 140 and 240, respectively, both designed for big game hunting. Big game reticles 140 and 240 may be substituted for reticle 40 in riflescope 10 (FIGS. 1 and 2). The aiming marks of big game reticles 140 and 240 are generally thicker than those of varmint reticle 40, affording better reticle visibility in low light conditions common to early morning hunts. And because big game animals are larger than varmints, they are less likely to be obscured by the larger marks and lines of big game reticles 140 and 240. In contrast, the aiming marks of varmint reticle 40 are made finer to afford greater target visibility and more accurate shot placement.

The thickness of fine central portions 58 of primary horizontal and vertical sight lines 52 and 54 (and secondary horizontal sight lines 72a-c, described below) may be sized, for example, to subtend an angle of approximately 0.13 minute of angle (MOA) in the field of view, wherein 1 MOA= 1/60th degree. Primary horizontal and vertical sight lines 52 and 54 may include one or more widened post portions 62 and 64, respectively, located radially outward from primary aiming point 50. Post portions 62 and 64 may be at least two times thicker than central portions 58 of primary horizontal and vertical sight lines 52 and 54, and more preferably three times thicker, to draw a shooter's eye to the thinner central portions 58 and thereby help the shooter to locate primary aiming mark or point 50. In some embodiments, innermost ends 66 of widened post portions 62 and 64 may serve as reference points for range estimation or windage compensation, as described in further detail below.

Reticle 40 includes one or more secondary aiming marks 68a-c spaced below primary aiming mark 50 along a vertical axis intersecting primary aiming mark 50. In the embodiment shown, the vertical axis is coincident with vertical sight line 54 and is, therefore, not separately shown or numbered. More preferably, reticles in accordance with certain preferred embodiments may include at least two such secondary aiming marks, spaced apart at distances from the primary aiming mark 50 preselected to compensate for bullet drop at incremental ranges to a target. In the embodiment of FIG. 4, three secondary aiming marks 68a, 68b, and 68c are formed by the intersection of secondary horizontal sight lines 72a, 72b, and 72c with primary vertical sight line 54. Alternatively, the secondary aiming marks need not be formed by intersecting horizontal and vertical lines, but may comprise other kinds of marks and indicia spaced apart below primary aiming mark 50. For example, in big game reticle 140 of FIG. 5, secondary aiming points 168a and 168b are indicated by the tips of opposing left and right CPC™-style secondary aiming marks 180a and 180b. Although each of the triangular CPC™-style secondary aiming marks 180a and 180b tapers to a sharp tip shown touching primary vertical sight line 154, in alternative embodiments (not shown), secondary aiming marks 180a and 180b need not touch primary vertical sight line 154 to indicate the location of secondary aiming points 168a and 168b. Thus, depending on the design preference, the secondary aiming marks may or may not overlap with, contact, or extend through the vertical axis or a primary vertical sight line to indicate the position on the vertical axis of the secondary aiming points 168a and 168b.

Turning again to FIG. 4, secondary aiming marks 68a-c are preferably arranged for accurate indication of bullet drop at incremental ranges when riflescope 10 is sighted-in at 200 yards—i.e., when the optical alignment of riflescope 10 relative to a barrel 44 of rifle 14 is adjusted so that primary aiming mark 50 accurately indicates a point of bullet impact 200 yards from the shooter. When riflescope 10 is sighted-in at 200 yards, secondary aiming marks 68a, 68b, and 68c will indicate points of impact at ranges of approximately 300, 400, and 500 yards, respectively, assuming the shot is not affected by crosswinds or lateral drift. Spacing of secondary aiming marks 68a-c for aiming at incremental ranges of round numbers makes it easy for a shooter to remember the ranges corresponding to the primary and secondary aiming marks 50 and 68a-c, and avoids the need to look away from the target to check a reference list of corresponding ranges, as with the riflescopes of U.S. Pat. Nos. 6,032,374 of Sammut and 6,591,537 of Smith. Moreover, in riflescopes according to the preferred embodiments, the optical power can be adjusted to compensate for different ammunition having different ballistics, as described below with reference to FIG. 7.

As indicated by dimension lines 74a, 74b, and 74c, the angles subtended between primary aiming point 50 and secondary aiming marks 68a, 68b, and 68c in the preferred embodiment are, respectively, 1.81 MOA, 4.13 MOA, and 7.02 MOA, at 16× magnification. When varmint reticle 40 is embodied in a transparent reticle disc located at rear focal plane 32 of riflescope 10, the actual physical dimensions of reticle lines and spacing between lines are determined based on the conversion factor of approximately 1.0 MOA=0.223 mm.

Similarly, secondary aiming marks 180a-b and 280a-b of respective second and third embodiment reticles 140 and 240 are spaced below primary aiming marks 150 and 250 for accurate indication of bullet drop at incremental ranges of 300 and 400 yards, when riflescope 10 is sighted-in at 200 yards. Because big game reticles 140 and 240 are designed to be used at a lower optical power and for a different type of ammunition than varmint reticle 40, the spacing between primary aiming mark 150/250 and secondary aiming points 168a/268a and 168b/268b is different from the corresponding spacing of secondary aiming marks 68a-b of varmint reticle 40. Preferably the 300-yard secondary aiming points 168a and 268a are spaced 2.19 MOA below the center of primary horizontal sight line 152/252 (i.e., primary aiming mark 150/252), at 10× magnification; and the 400-yard secondary aiming marks 168b and 268b are spaced 4.80 MOA from the center of primary horizontal sight line 152/252, at 10× magnification. Additional secondary aiming marks may be provided for compensating for bullet drop at longer ranges. For example, a 500-yard aiming mark 178/278 comprises the upper end of a lower post 164/264 in each embodiment, and a 450-yard aiming mark 176/276 comprises a short line intersecting primary vertical sight line 154/254. 450-yard aiming marks 176 and 276 are located 6.26 MOA below primary horizontal sight line 152/252 (measured center to center) and the 500-yard aiming marks 178 and 278 are located 7.82 MOA below the center of primary horizontal sight line 152/252, both measured at 10× magnification. When big game reticles 140 and 240 are embodied transparent reticle discs adapted to be located at rear focal plane 32 of riflescope 10, the actual physical dimensions of reticle markings and spacing therebetween on reticle discs are determined based on the conversion factor of approximately 1.0 MOA=0.139 mm.

Turning again to FIG. 4, varmint reticle 40 preferably includes a simple ranging device 76 for estimating the range to average-sized varmints and other targets that are approximately 7 inches in height. Ranging device 76 comprises a horizontal ranging line 78 positioned 2.333 MOA below the lowermost secondary aiming mark 68c at 16× magnification (a typical operating setting for varmint hunting), so that when a 7-inch-tall varmint 80 or another 7-inch target is located at 300 yards it will be closely bracketed in the gap 82 between secondary aiming mark 68c and ranging line 78. If a targeted varmint 80 is larger than gap 82, then it is closer than 300 yards and primary aiming mark 50 (or one of the associated windage aiming marks 86, described below) can be used for targeting. When a targeted varmint 80 is smaller than gap 82, the range is greater than 300 yards; thus, before selecting an aiming point, the shooter may want to use a precision ranging device such as a laser rangefinder, for example, to determine a more accurate range to the target.

A set of windage aiming marks 84 may be spaced apart along at least one secondary horizontal axis 88 intersecting a selected one of secondary aiming marks 68a-c, to facilitate compensation in aiming for the effect of crosswinds on the trajectory of the projectile. As with secondary aiming marks 68a-c, windage aiming marks 84 need not touch the corresponding secondary horizontal sight line 72a-c to indicate the location of windage aiming points on the secondary horizontal axis 88. However, in a preferred embodiment, windage aiming marks 84 include tick marks 92a and 92b intersecting or touching the ends of one or more of the secondary horizontal sight lines 72a-c and FLOATING SQUARE™ marks 94a and 94b for compensating for stronger crosswinds. First and second windage aiming marks 92a and 94a are spaced apart to the left of the vertical axis at distances from the vertical axis selected to compensate for leftward crosswinds of preselected first and second incremental velocities, respectively, at the incremental ranges of the corresponding secondary aiming mark. In the preferred embodiment, windage aiming marks 92a and 94a are positioned to compensate for first and second incremental crosswind velocities of 10 mph and 20 mph, respectively. Third and fourth windage aiming marks 92b and 94b are spaced apart to the right of the vertical axis at distances from the vertical axis selected to compensate for rightward crosswinds of preselected third and fourth incremental velocities, respectively, at the range of said selected secondary aiming mark. To simplify use of the reticle, the third and fourth windage aiming marks 92b and 94b are spaced to compensate for rightward crosswinds of third and fourth incremental velocities which are equal and opposite the respective first and second incremental velocities of the leftward crosswinds. Additional windage aiming marks 86 (also indicated as 92a-b and 94a-b) may be provided along primary horizontal sight line 52 for windage compensation at the sighted-in range (e.g., 200 yards) and the preselected crosswind velocities (e.g., 10 mph and 20 mph).

FIG. 10 is a view of the reticle of FIG. 3 shown aimed at a varmint 120 (not to scale) at a known or estimated range of 400 yards and compensating for a known or estimated leftward (right-to-left) crosswind of 20 mph.

Table 1 sets forth the spacing of windage aiming marks 92a/92b and 94a/94b at the selected incremental ranges of primary and secondary aiming marks 50 and 68a-c:

TABLE 1
	Horizontal distance	Horizontal distance	Distance from
	from vertical axis to	from vertical axis to	aim point 50
Range/	1st and 3rd windage	2nd and 4th windage	to post ends
corresponding	aiming marks 92a/92b	aiming marks 94a/94b	66 (30-mph
sight line	(10-mph crosswind)	(20-mph crosswind)	crosswind)
200 yds./line 62	1.77 MOA	3.54 MOA	5.31 MOA
300 yds./line 72a	2.86 MOA	5.72 MOA	—
400 yds./line 72b	4.09 MOA	8.17 MOA	—
500 yds./line 72c	5.49 MOA	10.99 MOA	—

Although the preferred embodiment of FIG. 4 shows a reticle 40 with four windage aiming marks 92a, 92b, 94a, and 94b at each range, greater or fewer than four windage aiming marks may also be used at each range. For example, as indicated in Table 1, at the sighted-in range of 200 yards, innermost ends 66 of post portions 62 may serve as a third pair of windage aiming marks, providing windage compensation for 30-mph crosswinds.

In the reticle 140 of FIG. 5, secondary aiming marks 180a and 180b are sized so that their outermost ends 192a and 192b are positioned to compensate for respective leftward and rightward 10-mph crosswinds. Marks 180a/180b at the 300-yard range (at secondary aim point 168a) are sized so that their ends 192a and 192b are located 2.16 MOA from the vertical axis. Marks 180a/180b at the 400-yard range (at secondary aiming point 168b) are sized so that at 10× magnification their ends are located 3.03 MOA from the vertical axis.

In the reticle 240 of FIG. 6, secondary aiming marks 280a and 280b are stepped to include radially outer post portions 284. Inner and outer ends 286 and 288 of post portions 284 are positioned to correct for crosswinds of 10 mph and 20 mph, respectively. At the 300-yard range (secondary aiming point 268a), inner ends 286 of post portions 284 are located 2.16 MOA from the vertical axis and outermost ends 288 are located 4.32 MOA from the vertical axis, both at 10× magnification. At the 400-yard range (secondary aiming point 268b), inner ends 286 of post portions 284 are located 3.03 MOA from the vertical axis and outer ends 288 are located 6.06 MOA from the vertical axis, both at 10× magnification.

The particular subtensions of secondary aiming marks 68, 168, and 268 are selected based on a survey of ballistic drop data for a variety of commonly used ammunition, which may be gathered empirically or calculated using the Ingalls Tables or ballistics software. FIG. 8 is a table including ballistics drop data for selected ammunition commonly used in big game hunting, for ranges of 300, 400, and 500 yards and based on a sighted-in distance of 200 yards. A nominal design for secondary aiming marks 168a-b and 178 was chosen to correspond to a 130 grain .270 caliber WINCHESTER (.270 WIN) bullet having a muzzle velocity of 3,000 feet per second (fps). The .270 WIN, 130 Gr., 3,000 fps was chosen as a nominal design because its ballistic characteristics are approximately median for a first group of ammunition 310 having ballistic characteristics within an acceptable error tolerance, at the selected incremental ranges. Based on ballistic calculations or empirical measurements at typical altitude, temperature and relative humidity, bullet drop for the .270 WIN, 130 Gr., 3,000 fps is determined to be approximately 6.88 inches at 300 yards. At a preselected nominal optical power of 10× magnification, 6.88 inches of ballistic drop converts to approximately 2.19 MOA below primary aiming point 50. Optical power of 10× magnification was preselected as the nominal optical power because it is commonly used for big game hunting. Subtensions for incremental ranges of 400 and 500 yards are selected in a similar manner, for the same nominal ammunition and 10× magnification.

One or more additional groups of ammunition having ballistic drop characteristics outside the acceptable error tolerance may also be selected. For example, ammunition of a second group 320 exhibits a greater amount of bullet drop than ammunition of first group 310. The present inventors recognized that to compensate for the different ballistic characteristics of ammunition of second group 320, the optical power of riflescope 10 could be decreased to thereby increase the subtensions of secondary aiming points 168a-b and 178. Thus, for example, an optical power of 7.5× magnification (a 25% decrease) is selected to provide a 25% increase in the subtension of secondary aiming mark 168a, to approximately 2.74 MOA (2.19 MOA×1.25=2.74 MOA), thereby corresponding to an approximate median ballistic drop of second group 320.

In the preferred embodiment, the ammunition is grouped into only two groups 310 and 320 for simplicity and ease of use. However, for more precise aiming, the same ammunition shown in FIG. 8 could be grouped into a greater number of groups, in which case ammunition other than .270 WIN might be selected as the nominal design. A group of ammunition may include as few as one particular kind of ammunition. The particular ammunition listed in FIG. 8 is merely exemplary. For the exemplary ammunition and based on the above-described grouping and optical magnification, FIG. 8 lists, at each of the incremental ranges of 300, 400, and 500 yards, the inches of error from the nominal design, the corresponding MOA at the preselected optical power, the deviation from nominal (in percent), and the corresponding approximate best optical power. This data, and especially approximate best optical power, is used to group the ammunition.

In yet other embodiments, different ammunition may be utilized at the settings corresponding to one of the groups, but at different incremental ranges. For example, .300 Ultra Mag (UM) ammunition 330 was determined to have ballistic drop characteristics that fall outside of the acceptable tolerance ranges for both of the first and second groups 310 and 320 of ammunition (i.e., more than 2.0 inches of deviation from nominal at 300 yards and nearly 11.5 inches of deviation from nominal at 500 yards). However, for the same .300 UM ammunition, if riflescope 10 is sighted-in at 300 yards instead of 200 yards (as indicated in FIG. 8 at 340), then secondary aim points 168a, 168b, and 178 can be used effectively to compensate for ballistic drop at 400, 500, and 600 yards, respectively, with an acceptable margin of error.

To facilitate adjustment of the subtensions of the secondary aiming marks for different groups of ammunition, a set of fiducial marks can be associated with power selector ring 34 to indicate the prescribed optical power settings for the different groups. FIG. 7 is a an enlarged partial pictorial view of the eyepiece end of riflescope 10 showing detail of power selector ring 34 and a portion of the right side housing 20. A dot 380 or other mark on housing 20 is used in cooperation with optical power indicia 386 on power selector ring 34 to indicate the optical power setting of riflescope 10. A set of fiducial marks 390 is also provided and includes, in the preferred embodiment, first and second fiducials 392 and 394 corresponding to the first and second groups of ammunition 310 and 320 listed in FIG. 8. In preparation for using riflescope 10, the shooter selects one of the fiducial marks 390 corresponding to the group of ammunition including the caliber of rifle 14 and type of ammunition to be used, and then rotates power selector ring 34 until the selected fiducial mark is aligned with dot 380. The relative large and small sizes of fiducials 392 and 394 are generally suggestive of the relative muzzle velocities and masses of the groups of ammunition, to help remind the shooter of the ammunition to which fiducials 390 correspond. Many other configurations and arrangements of power selector mechanism and fiducials may be used in place of the embodiment shown.

Riflescope 10 and reticles 40, 140, and 240 may also include a built-in range estimator. FIG. 9 is an auxiliary view of reticle 140 of FIG. 5 being used for range estimation. With reference to FIG. 9, the range estimator utilizes a known spacing between the ends 166 of post portions 162 and 164 (also called the “pickets”) and the central primary aiming mark 150 at a known magnification to estimate the range to targets of a known or estimated size. For example, ends 166 are spaced between approximately 7 MOA and 8 MOA from primary aiming mark 150 at the lowest optical power setting of riflescope 10 and more preferably approximately 7.6 MOA, which corresponds to approximately 16 inches at 200 yards. At the highest optical power—three times the lowest power for a zoom ratio of 3:1—the spacing between ends 166 and primary aiming mark 150 corresponds to a 16-inch target at 600 yards. To estimate range, a hunter frames the back-to-brisket feature of a deer 360 (which is known to be approximately 16 inches in height) between primary horizontal sight line 152 and end 166 of vertical picket 164, rotating power selector ring 34 to adjust the optical power, as necessary. When the optical power is adjusted so as to closely frame the back-to-brisket feature of deer 360, the hunter then views a set of ranging fiducials 400 (FIG. 7) associated with power selector ring 34 to determine the range to target. In the preferred embodiment, ranging fiducials 400 shown as “4”, “5”, and “6” indicate ranges of 400, 500, and 600 yards, respectively. (Ranging fiducials “2” and “3” corresponding to 200 and 300 yards are obscured in FIG. 7.) By determining which of the ranging fiducials 400 is most closely aligned with a ranging dot 410 on housing 20, the hunter can then quickly determine (estimate) the range to target.

Projectile weapon aiming systems have been described herein principally with reference to their use with rifles and embodied as riflescopes. However, skilled persons will understand that projectile weapon aiming systems may include aiming devices other than riflescopes, and may be used on weapons other than rifles, which are capable of propelling projectiles along substantially predeterminable trajectories, e.g., handguns, crossbows, and artillery. Thus, it will be obvious to those having skill in the art that many changes may be made to the details of the above-described embodiments without departing from the underlying principles of the invention. The scope of the present invention should, therefore, be determined only by the following claims.

Claims

1. A method for aiming a projectile weapon that shoots a selected projectile having associated ballistic characteristics, comprising: based on at least the selected projectile, identifying a corresponding projectile group from at least two different predetermined groups of projectiles, each group having associated nominal ballistic characteristics;determining a range to a target;based on the range to the target and the nominal ballistic characteristics of the selected projectile group, determining an aiming adjustment for the projectile weapon; andaiming the projectile weapon based on the aiming adjustment.

2. The method of claim 1, wherein identifying a corresponding projectile group further includes each group having associated optical power characteristics.

3. The method of claim 1, wherein the selected projectile is a type of ammunition.

4. The method of claim 1, wherein the selected projectile is an arrow.

5. The method of claim 1, wherein the predetermined groups of projectiles includes at least two mutually exclusive groups of ammunition.

6. The method of claim 1, further comprising adjusting a setting of an aiming device based on the selected projectile group.

7. The method of claim 6, wherein adjusting a setting of an aiming device includes adjusting an optical power setting.

8. The method of claim 1, wherein the displaying of the recommended aiming adjustment comprises displaying a reticle in a riflescope, the reticle including a secondary aiming mark spaced below a primary aiming point.

9. The method of claim 1, wherein the aiming adjustment includes a holdover adjustment.

10. A method for aiming a projectile weapon, comprising: grouping multiple different types of ammunition into multiple groups based on ballistic characteristics of the ammunition, the groups including at least a first group and a second group, the first and second groups having different nominal ballistic characteristics, the ballistic characteristics of the ammunition of the first group falling within a first acceptable error tolerance from the nominal ballistic characteristic of the first group, and the ballistic characteristics of the ammunition of the second group falling within a second acceptable error tolerance from the nominal ballistic characteristic of the second group; anddisplaying an aiming adjustment for shooting at the target, based on a range to the target and the nominal ballistic characteristic of a selected one of the groups.

11. The method of claim 10 wherein grouping multiple different types of ammunition is further based on the corresponding approximate best optical power of the ammunition.

12. The method of claim 10, wherein the ballistic characteristics of the ammunition are bullet drop characteristics.

13. The method of claim 10, wherein the grouping of ammunition includes grouping based on bullet drop characteristics of the ammunition at multiple different ranges.

14. The method of claim 10, wherein the first and second groups of ammunition are mutually exclusive.

15. The method of claim 10, further comprising adjusting a setting of an aiming device based on the selected group.

16. The method of claim 10, wherein the providing of the recommended aiming adjustment comprises displaying a reticle in a riflescope, the reticle including a secondary aiming mark spaced below a primary aiming point.

17. The method of claim 10, further comprising determining the range to the target using a rangefinder.

18. The method of claim 10, wherein the aiming adjustment includes a holdover adjustment.

19. The method of claim 10, further comprising adjusting an aim of the projectile weapon based on the determined aiming adjustment.