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Comparison Levenhuk Rainbow 2L NG vs Levenhuk Rainbow 2L Plus

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Features
 
training
Typebiologicalbiological
Operation principleopticoptic
Magnification64 – 640 x64 – 640 x
Research method
 
light field
Lens and eyepiece
Turret3 lenses3 lenses
Lens
4х, 10х, 40х
4х, 10х, 40х(s)
Eyepiece
monocular
WF16x
 
diameter 23.2 mm
monocular
WF16x
45° incline
diameter 23.2 mm
Design
Object table
mobile
 
mobile
90x90 mm
Focuscoarsecoarse
BacklightlEDlED
Top illumination
Bottom illumination
Condenserthere is aN.A.=0.65
Diaphragmflat
Features
 
brightness control
General
Power source
mains 230 V
batteries
mains 230 V
batteries
In box
 
accessories and preparations set
Materialmetal
Added to E-Catalogseptember 2017september 2017

Features

General purpose of a microscope.

Nowadays, there are 4 main options for the appointment: children's, educational, laboratory and specialized microscopes. At the same time, different options (at least from the first three) may well be combined in one model — for example, the simplest and most inexpensive educational microscopes may well be positioned as children's, and the most advanced as laboratory ones. Here is a detailed description of the different destinations:

— Children's. The most simple and inexpensive microscopes, designed primarily for children who are taking their first steps in the natural sciences (as well as for other undemanding users who do not need particularly advanced functionality). Accordingly, such devices lack advanced features such as focus lock, Keller lighting, video outputs (for digital and opto-digital models), a trinocular with the ability to connect a camera, etc. In addition, the body can be made in bright colours, and in plastic is usually used as the body material. However, many children's microscopes are equipped with turrets for quick re-tuning of magnification, and the total magnification factor may well exceed 600x out of the box and 1000x in the top configuration.

— Educational. Microscopes well suited for teaching applications; sometimes such an appointment is even di...rectly indicated by the manufacturer. The specific functionality of such models is quite diverse, the type can also be different (both biological and stereoscopic). In general, devices of this specialization occupy an intermediate position between simple and inexpensive children's microscopes and advanced laboratory equipment. At the same time, there are many models that have a combined purpose — "children's / educational" or "training / laboratory". The first variety is simple and inexpensive, for educational purposes it is suitable mainly for school; the second option, in turn, can be useful even at the university faculty of natural sciences.

— Laboratory. The most advanced type of modern microscopes, designed for full-fledged laboratory research and other serious tasks. Accordingly, such models are not cheap, but they provide a high-quality image and, in general, have the most extensive functionality (although the specific set of features, of course, may be different). Among the features found in laboratory microscopes are a movable stage, installation of light filters, 2 types of illumination (lower and upper), Keller illumination, suitability for special microscopy methods (fluorescence, phase contrast), etc.

— Specialized. Microscopes of a specific design and purpose, one way or another different from more traditional models. These differences may vary; accordingly, the specific specialization also differs. So, recently, portable models for smartphones have gained quite significant popularity: with the help of a special clothespin, such a device is attached directly to the gadget opposite the main camera, and the smartphone screen plays the role of an eyepiece. Another popular variety is compact digital microscopes without their own screens, connected to PCs or laptops via USB, and even to smartphones via Wi-Fi (including via the Internet). This also includes professional equipment with a fairly narrow specialization: stereoscopes with special mounts for dental prosthetics, for soldering microcircuits, etc.; microscopes for metallurgical research; devices on a tripod with a remote rod, designed to inspect individual areas on general objects; comparative microscopes for ballistic and trace investigations in forensics; and etc.

Research method

Research methods applicable to this microscope model.

— Bright field. The most famous and widely used method of light microscopy. The object under consideration in such studies is placed on a light background, against which it looks darker. Note that different methods of illumination can be used for research: direct through, oblique, reflected. The first option (when the light from a lamp or a mirror under the stage shines through the sample) is optimal for studying transparent samples, the key details of which are darker than the general background. Typical examples are thin sections of animal and plant tissues. Oblique light is similar in application specifics, while it gives a grey background and is inferior to direct light in terms of backlight efficiency, but provides a more embossed image. As for reflected light, in this case it is indispensable when examining opaque objects: samples of ores and other materials, semiconductor wafers, etc. Anyway, bright-field microscopy well reveals, first of all, details that are noticeably different in light transmission or refractive index from the surrounding background (with through illumination), or give noticeable reflections / shadows (with reflected light).

— Dark field. A kind of opposite of bright-field research: the object under consideration or its individual elements are lighter than the surrounding background. However, this is not just a “negative” of the image, but a separate method with its own c...haracteristics. Illumination in dark-field microscopy is usually through, but it is carried out in a specific way: the middle of the light beam is blocked by a hood, and the light “cylinder”, passing through the condenser lens, turns into an “hourglass”. At the same time, in the narrowest place of such a "clock" there is a preparation, and towards the lens, the light cone expands so that it does not fall into the optics. Thus, the user sees in the microscope only the light scattered by the preparation and the dark background around. This method of research, among other things, allows you to identify "smooth" details that do not stand out sharply against the surrounding background and are not visible in a bright-field study. Among the applications of dark-field microscopy are the work with unstained biological preparations (cells, tissue samples, microorganisms), as well as the study of some transparent materials for small surface defects.

— Phase contrast. A method used to study transparent and colourless objects with an inhomogeneous structure, used when this inhomogeneity cannot be detected by more traditional bright-field microscopy. The idea of this method is that when passing through structures with different refractive indices, light receives different phase changes. These changes are not visible with ordinary optics, but they can be made visible with the help of special equipment — namely, a condenser and a lens of a special design. Accordingly, such equipment is necessarily included in the scope of delivery of the microscope.

— Fluorescent. This method provides the illumination of observed objects with light of a certain wavelength, under the influence of which these objects or their individual elements begin to glow, while the background remains dark. If necessary, coloring substances are introduced into the preparation to improve luminosity (a typical example is biological objects, most of which fluoresce rather weakly by themselves). For illumination, usually, UV radiation is used, therefore this method is also called ultraviolet microscopy; The image enters the eyepiece of the microscope through a filter that filters out UV rays, but freely passes the visible glow of the drug.
One of the main features of fluorescence microscopy is high resolution: it allows you to clearly see even very small objects that are not visible in the usual visible range. In fact, this method in terms of resolution is between classical optical and electron microscopy; At the same time, in contrast to electron and atomic microscopes, devices with the support of the UV method make it possible to examine even the hardware of living cells and microorganisms. And some special variants of this technique make it possible to achieve not micro, but nanoscopic magnifications. The second popular use of fluorescence microscopy is the detection of particles, elements, inclusions, etc., which are not visible under ordinary light, but stand out well in ultraviolet light. A typical example is the surface of many metals and alloys.

Lens

Zoom lens. Lens with variable magnification. Such optics allow you to smoothly change the overall magnification of the microscope within certain limits, without changing the objective/eyepiece and without even looking up from observations. On the other hand, zoom lenses are more complicated and more expensive than constant magnification optics. Therefore, they are mainly used in stereoscopic microscopes (see "Type"): in the repair, assembly and other tasks for which such devices are used, the ability to smoothly adjust the multiplicity is extremely useful.

— magnification factor. The magnification provided by the lens. This parameter, along with the magnification of the eyepiece, affects the overall magnification of the device (see above). Most biological microscopes (see "Type") are equipped with several different magnification objectives on the turret; this allows you to adjust the degree of magnification as desired by the user. The standard magnification options for such lenses are 4x, 10x, 40x, 100x.

— Achromat. One of the varieties of colour correction used in lenses. The need for colour correction is due to the fact that light of different colours is refracted differently by lenses, and without additional measures, the image in the microscope would be blurred with iridescent stains. Achromatic is one of the simplest types of colour correction; in such optics, colour distortions in yellow and green are corrected.... Achromatic lenses have simple design and low cost. However the image quality in them is far from perfect: such a lens gives a clear image only in the centre of the image, the width of the sharpness zone is about a third of the total width of the field of view, and red-blue streaks may appear along the edges of the image. However, this is quite enough for general acquaintance, initial training, and often for more serious tasks.

— Planachromat. An improved and improved version of achromatic lenses (see above). Plan achromats provide additional correction of the field curvature, due to which the area of a clearly visible image in such lenses is at least 2/3 of the total width of the field of view, and often even more. It is these lenses that are recommended for serious study and professional use.

— Rim diameter. The size of the thread used to mount the lens. A larger bore usually means a wider lens, which means higher aperture and better image quality. On the other hand, the large size affects the dimensions, weight and cost of optics. In modern microscopes, diameters from 20 to 35 mm are mainly found. Knowing the size of the thread, you can purchase replacement or spare lenses for the device.

Eyepiece

Monocular. An eyepiece with a single lens that can only be viewed with one eye. For obvious reasons, it is only used in biological microscopes (see "Type"). The advantages of monoculars are primarily smaller size and cost than other varieties; in addition, they do not require adjustment for interpupillary distance. On the other hand, constantly looking into the eyepiece with one eye is tiring, so this option is poorly suited for situations where you have to look into the microscope often and for a long time.

Binocular. Dual eyepiece that can be viewed with both eyes at once. Note that such optics are used not only in stereomicroscopes, originally intended for viewing an object through two lenses (see "Type"), but also in biological microscopes with one lens. The fact is that looking into an optical device with two eyes is much more convenient than with one, while the eyes are less loaded and fatigue does not occur so quickly. Therefore, for serious tasks associated with frequent use of a microscope, binoculars (or trinoculars, see below) are the best option. Such optics cost more than monocular, but this is offset by ease of use.

Trinocular. A kind of binocular (see the relevant paragraph), supplemented by a third optical channel for a special camera-video eyepiece. Such a camera is usually connected to a PC or laptop; by installing it in the soc...ket for the third eyepiece, you can take photos and videos, as well as display the image in real time on the computer screen. At the same time, you can look through the microscope in the usual way. Devices with trinoculars are very functional and versatile, but they are complex and expensive.

— LCD screen. The microscope has an LCD screen that replaces the traditional eyepiece. You do not need to bend over to such a device each time to view the image, which is very convenient if observations need to be combined with record keeping and other similar activities. Microscopes of this design usually have a photo and video function, as well as various built-in tools — for example, a scale grid for estimating the size of visible objects, displayed directly on the screen. In addition, the image on the screen can be seen not only by the direct user, but also by everyone who is nearby; such features are indispensable during training sessions, consultations, presentations, etc. On the other hand, such microscopes turn out to be bulky and expensive.

— magnification factor. The magnification provided by the eyepiece. This parameter, along with the lens magnification, affects the overall magnification of the device (see above). The classic option for eyepieces in microscopes is 10x, but higher values \u200b\u200bare also found. The package may include several eyepieces, of different magnification — to change the overall degree of magnification. There is a multiplicity designation with a letter index, for example, WF10x. This means that the eyepiece has an extended field of view (WF — wide, EWF — extra wide, UWF — extra wide).

— Eyepiece tilt. The tilt of the eyepiece determines the position of the observer's head when looking through the microscope and the overall usability. According to this indicator, three main options can be distinguished: fixed angle, adjustable angle, without tilt. The fixed angle is most often 30° or 45° relative to the horizontal, these values are considered the most convenient. In angle-adjustable microscopes, the entire stand, with tube and stage, is fixed to the base with a swivel mount. This is the most convenient option, allowing you to adjust the tilt to your preference, but the mount tends to become loose over time, so it is rarely used in professional microscopes. The third variety — vertical microscopes, without tilt — have not received much distribution: this design is used in some stereoscopic models (see "Type") in order to ensure that the stage remains strictly horizontal (this is important for some work with microscopic objects).

— Rim diameter. The nominal diameter of the eyepiece used in the microscope, as well as the diameter of the hole in the tube, designed to install the eyepiece. Several standard diameters are used in modern microscopes, in particular 23 and 27 mm. In fact, this parameter is necessary, first of all, if you plan to purchase spare or replacement eyepieces for the microscope, or if you already have an eyepiece on the farm, and you need to evaluate its compatibility with this model.

— Diopter adjustment. The range of diopter correction provided in the eyepiece. This correction is used so that a nearsighted or farsighted person can look through the microscope without glasses or contact lenses. In most models with this function, the correction range is about 5 diopters in both directions; this allows the microscope to be used for low to moderate myopia/farsightedness.

Object table

The design of the object stage provided in the microscope.

— Stationary. Subject table, fixed motionless; focus in such microscopes is carried out by moving up and down the tube with the objective and the eyepiece. Such systems are simple and inexpensive, but focus while looking through a constantly moving eyepiece is not very convenient. In addition, for advanced biological microscopes (see "Type") with binoculars and trinoculars (see "Eyepiece"), this option is also poorly suited for some design reasons. But the vast majority of stereomicroscopes are equipped with stationary tables — this is the most reasonable design, taking into account the specifics of the application.

Movable. In microscopes of this type, the entire optical system is fixedly fixed on a tripod, and the stage can be moved up and down to focus the optics. This design is found exclusively in biological microscopes (see "Type"). It is somewhat more complicated and expensive than with a fixed table, but at the same time it is much more convenient: when focus, the eyepiece does not move, which allows you to comfortably adjust the image without looking up. In addition, it is the movable stage that is most suitable for advanced devices with binoculars and trinoculars (see "Eyepiece"), almost all such microscopes have such equipment.

Bottom illumination

Bottom lighting is a lighting system, the light from which is directed from the bottom up.

In conventional (not inverted) microscopes, such illumination is directed towards the objective through a hole in the stage. It is this type of illumination that is used for classical bright-field microscopy using through illumination; Thus, the lower arrangement of the illumination is traditional for biological microscopes and is provided for in most of these models. But the presence of this function in "stereoscopes" is not typical, although it also occurs.

In turn, in inverted microscopes, the upper and lower illuminations are actually “swapped”. Accordingly, in such models, this function is intended for examining preparations (mostly opaque) in reflected light, and the light flux is directed from the lens to the preparation.

Condenser

Features of the design of the condenser installed in the microscope.

The condenser is part of the illumination system in biological microscopes (see "Type"). This is an optical system that processes the light flux entering the preparation glass in a special way. Different situations may require different ways of doing this; accordingly, different types of condensers can be used in microscopes. However, the most popular nowadays is the simplest Abbe condenser. It ensures the concentration of the beam of light and its uniform distribution over the field of view. Initially, such a device was intended for studies using the bright field method, but it can also be used for phase-contrast observations. The Abbe condenser can be equipped with an iris aperture diaphragm — with its help you can reduce the brightness of the illumination — as well as colour filters.

Other, more specific types of condensers (for example, phase or dark field) are usually purchased separately and are rarely included in the standard microscope equipment.

The characteristics of the condenser may indicate NA — the size of the aperture (active hole) in millimetres, for example, NA \u003d 1.2. This is a rather specific setting; suffice it to say that it is selected by the manufacturer for complete lenses and does not fundamentally affect the choice of a microscope.

Diaphragm

The type of diaphragm installed in the microscope.

The diaphragm is a device that partially blocks the flow of light from the microscope lighting system. It is used mainly for adjusting lighting, as well as for some more specific tasks (in particular, changing the depth of field). When adjusting the diaphragm, the size of its working opening changes - and, accordingly, the actual light transmission; and different types of diaphragms ( iris or rim) differ in adjustment features:

- Iris. The name comes from the Latin word for the iris of the eye - similar devices work on a similar principle. The iris diaphragm consists of a set of specially shaped blades (the so-called lamellas). When moving to close, these petals move from the edges of the working hole to the center, reducing its size; when opening, they correspondingly move outward. Iris diaphragms are more complex and more expensive than rim diaphragms, but they have a number of important advantages over them. First of all, the light transmission throughout the entire operating range of such devices changes smoothly, which allows you to select the settings as accurately as possible. You can manage the settings without interrupting your monitoring of the drug; At the same time, iris diaphragms are also as compact and lightweight as possible. As a result, this option is the most popular in microscopes of the middle class and above, and...is also often found even in simpler models.

- Disk. Another name is revolver. This type of diaphragm is a rim with holes of different sizes made in it; By rotating the rim, you can place different holes in the field of view of the microscope and, thus, change the light transmission. The main advantages of such devices are simplicity of design, low cost, reliability and ease of repair. On the other hand, disc diaphragms are less practical and sophisticated than iris diaphragms - in particular, they are very bulky and do not allow for smooth adjustment. In light of this, this option is used mainly among entry-level microscopes, where advanced characteristics are not required - and an affordable price, on the contrary, is of key importance.

Features

Adjustment of interpupillary distance. The ability to change the distance between the eyepieces in a binocular or trinocular microscope (see "Eyepiece"). For normal visibility, it is necessary that the distance between the lenses of the eyepieces correspond to the distance between the pupils of the user. This distance varies from person to person, so this setting may be required for comfortable use.

Brightness adjustment. The ability to change the brightness of the backlight — to adjust the lighting to the specifics of the situation. For example, to study a thin transparent preparation in a bright field, high brightness will be unnecessary, but when transilluminating a dense dark object, it is indispensable.

Illumination according to Keller. The presence of illumination in the microscope according to the Keller system. Such lighting is used exclusively in biological models (see "Type"), it is a sign of a professional level device. The Keller system complicates and increases the cost of the design, in addition, it may require specific settings, but with the right settings, the quality of the lighting is very high, and the image is as reliable as possible. Note that in microscopes there is a so-called. "simplified Keller system", when the settings are set at the factory and cannot be changed; however, in this case, it is precisely the full-fledged,...adjustable Keller lighting that is meant.

Photo / video recording. Possibility of photo and video filming of the image visible in a microscope. Features of the implementation of this function in different microscopes may be different. For example, some models need to be connected to a computer, while others can record materials directly to a memory card or other media. Also, the cameras themselves, carrying out the shooting, can be both built-in and removable (see "Packaging" / relevant paragraphs).
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