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Comparison Canon 10x42 L IS WP vs Bushnell H2O 10x42 Roof

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Canon 10x42 L IS WP
Bushnell H2O 10x42 Roof
Canon 10x42 L IS WPBushnell H2O 10x42 Roof
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from 9 950 ₴
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Product typebinocularsbinoculars
Magnification10 x10 x
Optical characteristics
Optical stabilizer
Field of view 1 km away114 m102 m
Apparent angular field65 °
Min. focus distance2.5 m3.6 m
Twilight factor20.520.5
Relative brightness17.617.6
Design
Lens diameter42 mm42 mm
Exit pupil diameter4.2 mm5 mm
Eye relief16 mm17 mm
Focuscentralcentral
Anti reflective coatingmultilayer
PrismPorroRoof
Prism materialBaK-4
Interpupillary adjustment
Interpupillary distance57 – 75 mm
Nitrogen filled
General
Dustproof, water resistant
Case
Tripod adapter
Bodyrubberized plastic
Size137x85x176 mm
Weight1030 g709 g
Color
Added to E-Catalogseptember 2014july 2014

Optical stabilizer

The presence in the design of the device of an optical image stabilization system — similar to those used in lenses for photographic and video equipment. The effect of such stabilization is based on the use of movable lenses and gyroscopes, which monitor small tremors of the device and make the necessary adjustments to the operation of the optics so that the visible “picture” remains motionless. This function is especially useful at high magnifications, as well as when holding the device in your hands; at the same time, it significantly complicates the design and increases the cost, and also requires a power source (usually in the form of batteries).

Field of view 1 km away

The diameter of the area visible through binoculars / monoculars from a distance of 1 km — in other words, the largest distance between two points at which they can be seen simultaneously from this distance. It is also called "linear field of view". Along with the angular field of view (see below), this parameter characterizes the space covered by the optics; at the same time, it describes the capabilities of a particular model more clearly than data on viewing angles. Models with magnification adjustment (see above) usually indicate the maximum field of view — at the lowest magnification and the widest angle of view. This information is often supplemented by data on the minimum value.

Apparent angular field

The angle of view provided by binoculars/monoculars and available to the eye of the observer. This parameter can be described as the angle between the lines connecting the two extreme points of the image visible in the eyepiece with the eye of the observer; in other words, this is the sector actually observed through binoculars (as opposed to the actual angular field of view described below). The greater the value of this parameter, the greater part of the observed space can be seen without turning the instrument. On the other hand, a wide field of view reduces the magnification factor (see above) — or significantly increases the cost of the device compared to more focused ones.

Min. focus distance

The smallest distance to the observed object, at which it will be clearly visible through binoculars / monoculars. All such optical instruments were initially created for observing remote objects, therefore, not all of them are able to work at short distances. When choosing a model for this parameter, one should proceed from the expected observation conditions: ideally, the minimum focus distance should not be greater than the smallest possible distance to the observed object.

Exit pupil diameter

The diameter of the exit pupil created by the optical system of a binocular/monocular. The exit pupil is called the projection of the front lens of the lens, built by the optics in the region of the eyepiece; this image can be observed in the form of a characteristic light circle, if you look into the eyepiece not close, but from a distance of 30 – 40 cm. The diameter of this circle is measured according to a special formula — dividing the diameter of the lens by the multiplicity (see above). For example, an 8x40 model would have a pupil diameter of 40/8=5mm. This indicator determines the overall aperture of the device and, accordingly, the image quality in low light: the larger the pupil diameter, the brighter the “picture” will be (of course, with the same quality of prisms and glasses, because they also affect the brightness). In addition, it is believed that the diameter of the exit pupil should be no less than that of the pupil of the human eye — and the size of the latter can vary. So, in daylight, the pupil in the eye has a size of 2-3 mm, and in the dark — 7-8 mm in adolescents and adults, and about 5 mm in the elderly. This point should be taken into account when choosing a model for specific conditions: after all, fast models are expensive, and it hardly makes sense to overpay for a large pupil if you need binoculars exclusively for daytime use.

Eye relief

The offset is the distance between the eyepiece lens and the exit pupil of an optical instrument (see "Exit Pupil Diameter"). Optimum image quality is achieved when the exit pupil is projected directly into the observer's eye; so from a practical point of view, offset is the distance from the eye to the eyepiece lens that provides the best visibility and does not darken the edges (vignetting). A large offset is especially important if the binoculars / monoculars are planned to be used simultaneously with glasses — because in such cases it is not possible to bring the eyepiece close to the eye.

Anti reflective coating

Coating is a special coating applied to the surface of the lens. This coating is intended to reduce light loss at the air-glass interface. Such losses inevitably arise due to the reflection of light, and the antireflective coating “turns” the reflected rays back, thus increasing the light transmission of the lens. In addition, this function reduces the amount of glare on objects visible through binoculars/monoculars. There are single-layer, full single-layer, multi-layer, full multi-layer. More details about them:

- Single layer. This marking indicates that one or more lens surfaces (but not all) have a single layer of anti-reflective coating applied to them. This is inexpensive and can be used even in entry-level optical instruments. On the other hand, it filters out a certain spectrum of light, which distorts the color rendition in the visible image - sometimes quite noticeably. In addition, in this case, on some lens surfaces there is no coating at all, which inevitably leads to glare in the field of view. Thus, single-layer coating is the simplest type and is used extremely rarely, mainly in budget models.

- Full single layer. A variation of the single-layer coating described above, in which an anti-reflective coating is present on all surfaces of the lenses (at each air-glass interface). Although this...option is also characterized by color distortion, it is devoid of another, the most key drawback of “incomplete” enlightenment - glare in the field of view. And the mentioned color distortion is most often not critical. With all this, full single-layer coating is relatively inexpensive, which is why it is very popular in entry-level and entry-mid-level models.

- Multi-layered. A type of coating in which multiple layers of reflective coating are applied to one or more lens surfaces (but not all). The advantage of such a coating over a single-layer coating is that it uniformly transmits almost the entire visible spectrum and does not create noticeable color distortions. The absence of a coating on individual surfaces reduces the cost of the device (compared to full multi-layer coating), but it is impossible to completely get rid of glare in such a system.

- Fully multi-layered. The most advanced and effective of modern types of coating: a multilayer coating is applied to all surfaces of the lenses. This way, high brightness and clarity of the “picture” is achieved, with natural color rendition and no glare. The classic disadvantage of this option is its high cost; Accordingly, full multi-layer coating is typical mainly for high-end models.

Prism

A type of prism used in binocular/monocular construction. A prism is one of the key elements of an optical system: it is a glass polyhedron through which light passes on its way from the lens to the eyepiece. The need to use such polyhedra is associated with the peculiarities of the creation of optical devices of high multiplicity. In other models, there are two main options:

Porro. A distinctive feature of binoculars with such prisms is that the optical axes of the eyepieces are offset relative to the lenses — in other words, the distance between the eyepieces differs from the distance between the output lenses. This makes the design somewhat more cumbersome than with Roof prisms; on the other hand, the lenses can be spread over a long distance, which provides a better sense of the volume of the observed picture — especially at long distances. In addition, binoculars with Porro prisms are easier to equip with interpupillary distance adjustment (see below).

Roof. In models with prisms of this type, the eyepiece and the objective are on the same optical axis — the binoculars look as if the light in it goes from "input" to "exit" directly, without any prism at all (although in reality this, of course, is not So). Such devices are smaller and lighter than Porro systems, but more complex and more expensive.

Prism material

Material used for prisms found in binoculars and monoculars.

- BK-7. A type of borosilicate optical glass (6LR61), a relatively inexpensive and at the same time quite functional material that provides, although not outstanding, quite acceptable image quality. Used in entry-level and mid-level models.

—BaK-4. Barium optical glass, noticeably superior to BK7 in brightness and image clarity, is however also more expensive. Accordingly, it is found mainly in the premium segment.
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