Cloud storage
Compatibility of the camera with one or another
cloud storage. This paragraph may indicate the very fact of compatibility or specify the specific service (services) for which the device is designed — usually it is Google Drive or Yandex Drive, and often both at once.
Recall that cloud storage is an information storage system located on remote servers. Data is transmitted to such a system via the Internet, and the owner can also access them via the World Wide Web, regardless of their own location. In addition, modern "clouds" allow you to share selected information with other users. The basic functionality of such services and a certain amount of disk space are usually available for free, but for advanced features and increased storage, payment is required (one-time or regular subscription, depending on the specific service).
Specifically, in this case, compatibility with cloud storage means that the camera is able to directly transfer footage and other information to such storage. This provides two important advantages at once. The first has already been mentioned — the ability to work with videos (view, copy, share, etc.) from almost anywhere in the world where there is access to the Internet. The second point is additional reliability and security: even if the surveillance system's own storage device (recorder, local server, etc.) is damaged or destroyed, a copy of the footage will still remain in the "cloud".
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...Br> Note that cloud storage support is also found in registrars with network capabilities. However, the purchase of cameras with such functionality is convenient because such cameras do not need additional equipment to work with the "cloud".Number of LEDs
The number of backlight LEDs (see "Design and capabilities") provided in the camera design.
Theoretically, more LEDs provide more power and, accordingly, range (see below) and efficiency
of IR illumination or LED illumination. However, in fact, such light sources can vary markedly in performance; in addition, a lot also depends on the features of the camera itself. Therefore, in fact, this indicator is a reference, and when choosing, it makes sense to pay attention to parameters that are closer to practice — in particular, the same backlight range (see below).
Illumination range
Operating range of the backlight (see "Design and capabilities") installed in the surveillance camera. This term usually means the maximum distance from the camera to the observed object, at which it is able to provide a relatively high-quality and legible image in the complete absence of other light sources. Of course, the actual backlight range may differ from the claimed one, and these differences are most often in the direction of increase (for example, due to the presence of the same additional light sources). However, if the possibility of shooting with backlight is important for you, you should focus on the claimed range.
Matrix size
The size of the matrix installed in the surveillance camera (diagonally).
In general, larger sensors (with the same resolution and sensor type) are considered more advanced: they get more light, which has a positive effect on image quality (especially in low light). On the other hand, increasing the size affects the cost of the entire device; and in some cases (for example, if the camera is not planned to be used in twilight and darkness), a relatively small sensor may be quite suitable.
As for specific dimensions, the most modest cameras in terms of this indicator have matrices of
1/4 "or less. Models with sensors of
1/3.8" - 1/3" and
1/2.9" - 1/2" are very popular, these values can be called average. And in advanced devices, diagonals and
more than 1/2 "(up to 1/1.7") are found.
Number of megapixels
Camera sensor resolution in megapixels (millions of pixels).
The higher the resolution of the matrix, the higher the video resolution can be (see below), the more detailed the image is capable of providing the camera. At the same time, note that as the number of megapixels increases (without changing the size of the matrix), the size of each individual pixel decreases, which increases the likelihood of noise and deterioration in the overall image quality. Therefore, high resolution in itself is not necessarily a sign of high quality — a lot depends on other things, for example, on the size of the matrix (see above).
As for specific values, in the most modest matrices it does not exceed 1.3 MP, which corresponds to the maximum
HD resolution.
2 MP sensors allow for already Full HD resolution (usually 1920x1080 or 1600x1200),
3 MP,
4 MP,
5 MP and
6 MP are capable of better resolution, but still do not reach
4K, which is typical for 8 MP.
Video resolution
The maximum video resolution that the camera can capture.
The higher the resolution of the video, the more details you can see on it, the less details will be blurry. On the other hand, high resolution means large volumes of video materials, which, accordingly, requires capacious media for their storage and fast communication channels for broadcasting video in real time. Yes, and this indicator significantly affects the cost of the camera.
Frame rate
The maximum frame rate in the video captured by the camera.
The higher the frame rate, the clearer the image, the less noticeable blurring when moving in the frame (especially fast). On the other hand, this indicator affects the amount of information recorded during shooting, as well as the cost of the camera itself. Therefore, it makes sense to specifically look for
a video surveillance camera with high-speed shooting(45 fps and higher) only if a clear recording of fast moving objects is important to you.
Aperture
Aperture of the lens installed in the camera.
Aperture characterizes the degree of attenuation of the light flux when passing from the front lens of the lens to the matrix. It is denoted as the ratio of the diameter of the active aperture of the lens to the focal length, while the size of the active aperture is designated as f and is taken as a unit — for example, f / 1.4 or f / 2.0. Moreover, the smaller the number in the designation, the higher the aperture (in our example, the second lens will be darker than the first). And for lenses with a variable focal length (see "Focal"), the actual aperture, usually, changes with a change in focal length; for such models, either the range of aperture values, or its maximum value, can be indicated.
By itself, this parameter characterizes, first of all, how light the image taken through the lens turns out, all other things being equal. High values are important, first of all, when shooting in low light conditions: a fast lens allows you to get a fairly high-quality image without increasing the sensitivity of the matrix, which is fraught with noise and “blurring” of the picture. On the other hand, the actual quality of camera operation (including in dark conditions) also depends on many other factors — the type and size of the matrix, signal processing features, etc. Therefore, aperture in most cases is more of a reference than a practically significant parameter.
Focal length
Focal length of the camera lens.
The focal length is such a distance from the lens to the matrix, at which a clear image is obtained on the matrix (when the lens is focused to infinity). The viewing angles of the lens primarily depend on this indicator (see below): the smaller it is, the wider the viewing angles and the smaller the objects in the frame (and vice versa). At the same time, it should be noted that the actual viewing angle is determined not only by the focal length, but also by the size of the matrix (see above). In fact, this means that with different sizes of matrices, lenses with the same focal length will have different working angles. Therefore, only cameras with the same matrix size can be compared with each other according to this indicator. Among CCTV cameras, lenses with a focal length of
2.8 mm,
3.6 mm,
4 mm and
6 mm are considered popular.
In models with a variable focal length (see above), in this case, the range from the minimum to the maximum distance is indicated. Also, using these data, you can derive the optical magnification factor of such a lens: for this, the maximum value must be divided by the maximum (for more details, see below).