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Comparison Anteniti 4G LTE MIMO 2x20 dbi vs Anteniti 4G LTE MIMO 17 dbi

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Anteniti 4G LTE MIMO 2x20 dbi
Anteniti 4G LTE MIMO 17 dbi
Anteniti 4G LTE MIMO 2x20 dbiAnteniti 4G LTE MIMO 17 dbi
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Features4G (LTE)4G (LTE)
Mountexternalexternal
MIMO
Directional patternbeamedsector
Polarizationvertical and horizontalvertical and horizontal
Frequency range
LTE 800
LTE 1800
LTE 2600
 
LTE 1800
LTE 2600
Wave drag50 Ohm50 Ohm
Gain20 dBi17 dBi
Connectorx2 FMEx2 FME
Dimensions240x70 mm200x200 mm
Weight1200 g
Added to E-Catalogdecember 2019september 2019

Directional pattern

Omnidirectional. As the name implies, such an antenna works equally effectively in all directions; its radiation pattern has the form of a circle. Such models are intended mainly for situations where the signal strength is relatively high, but the signal itself can come from any direction (and it also needs to be broadcast in all directions). For example, this option is convenient for general-purpose Wi-Fi antennas, both on routers (installed approximately in the centre of the covered space) and on receivers like laptops (which can be in different positions relative to the router). And in 3G communications, omnidirectional antennas are useful mainly in dense urban areas, where the distance to base stations is small, but the signal is constantly reflected and changes direction. Note that all antennas of this type have a relatively short range.

Directed. Antennas having a fairly narrow beam pattern — usually up to 60°, rarely up to 80° HBPW horizontally (see "HPBW / horizontal"). They are mainly used to organize communication on a point-to-point basis — for example, to connect a "home" 3G modem to the nearest base station or to connect a wireless access point to a Wi-Fi router in another building. A directional antenna needs to be pointed quite accurately, and such models are not suitable for use on the go. On the other hand, the narrowing of the beam has a positive effect on the gain and rang...e; it is these models that you should pay attention to if you need to receive a signal from a remote source or “break through” a thick concrete wall, which lacks the equipment’s own power.

— Sector. This type is a cross between the two varieties described above. The coverage angle of sector antennas is limited, but wider than directional models, ranging from 90° to 120° HBPW/H. Such devices are used mainly in Wi-Fi networks, when it is impossible to install a router in the centre of the covered space: they allow you to optimally distribute the signal from the edge of this space or even from the corner.

Frequency range

The frequency ranges for which the antenna was originally designed. Communication technologies (see "Intended use") supported by the product directly depend on this parameter. At the same time, each type of communication includes several ranges, usually not compatible with each other. Therefore, when choosing a Wi-Fi or 3G antenna, it is worth considering not only the general purpose, but also the ranges within this purpose. Here are the most popular options:

2.4 GHz. The most popular band used by modern Wi-Fi equipment. It is standard for the Wi-Fi 802.11 b/g standard and one of the standard ones for the 802.11n standard. Supported by most appropriate antennas (see above).

5 GHz. The Wi-Fi band first introduced in the 802.11n standard (used in parallel with 2.4 GHz) and the only standard for 802.11ac, the most advanced Wi-Fi standard to date. Note that 5GHz-only equipment may not be compatible with older Wi-Fi 802.11 b/g devices; therefore, for guaranteed compatibility, it is recommended to combine a 5 GHz antenna with a 2.4 GHz one, or use a universal model that supports both bands (these are also available).

— CDMA 450. In general, the CDMA standard is known in the post-Soviet space for services such as "landline number on a mobile phone", as well as one of the most popular ways to "home" Internet connection via mobile networks (EV-DO technology is used). In this c...ase, we are talking about CDMA communication using the 450 MHz band. Another popular band is 800 MHz; there is no fundamental difference between them, so both options are often used by operators within the same country and even region. However, CDMA450 and CDMA800 are not compatible with each other. Thus, before buying an antenna, you should definitely clarify which standard the selected mobile operator uses.

— CDMA 800. A CDMA communication standard using the 800 MHz band. See "CDMA450" above for details.

— GSM 900. GSM is a mobile communication standard that was extremely popular around the world some time ago. Today it is considered completely obsolete (primarily due to low bandwidth), it is gradually being replaced by more advanced 3G UMTS and 4G LTE formats. However, both of these formats are extensions of GSM, and such networks remain compatible with the original GSM equipment. In addition, inexpensive GSM modules are still used in some special devices that do not require high communication speed (alarm systems, payment terminals, etc.). Thus, antennas for this communication standard are still being produced. Specifically, GSM 900 (the numbers indicate the operating frequency in MHz) is the earliest GSM communication range that appeared in Europe and Asia. It is inferior to GSM 1800 in terms of energy efficiency and network capacity, but it has a longer range and works better in dense urban areas, which is why it is still used today. And even newer phones remain compatible with GSM 900.

— GSM 1800. The GSM range, created as a development and improvement of the GSM 900 described above, with a doubled operating frequency (up to 1800 MHz — hence the name). Due to this, it was possible to halve the radiation power, as well as increase the network capacity (the number of devices that can work in it simultaneously). On the other hand, GSM 1800 requires a denser arrangement of base stations, and the signal loses a lot of power when passing through walls. Therefore, devices with support for this range are made backward compatible with GSM 900.

— UMTS 2100. Standard range of mobile communication 3 generations (3G) of the UMTS standard. Usually, this connection is what they mean when they talk about a smartphone or tablet with 3G. Such networks have been deployed on the basis of the existing GSM infrastructure, however, due to the nature of the signal, UMTS requires antennas specially designed for this range.

In addition to those described above, modern antennas (primarily "mobile") may provide other ranges — for example, LTE 800, 1800, 2600 and 5G 700 MHz, 5G 3300 – 3800 MHz in models for the corresponding communication standard. However, this is extremely rare and usually as an adjunct to one of the more common options.

— LTE 800. One of the three most popular bands used by 4th generation LTE mobile communications in Europe and the post-Soviet space (although less popular than those described below). Also known as band 20, according to the official band numbering. Refers to the FDD format (see "Destination — 4G (LTE)").

— LTE 1800. The fourth generation mobile communication band, also known as band 3. Was the most popular in the world in 2016, and it is likely that this situation will continue for quite some time. In part, this popularity is due to the coincidence in frequencies with GSM 1800 and the ease of deployment of LTE networks in this range.

— LTE 2600. Another common 4th generation communication range; the second most popular, after LTE 1800, for 2016. According to the band table, it is called band 7. It is considered quite promising due to the very small amount of extraneous interference in its frequency band; many telecom operators are switching or planning to switch to LTE 2600 even despite the rather high cost of such a solution.

- 5G 700 MHz. One of the lowest bands for 5G networks, 700MHz has good indoor penetration and is suitable for high-speed mobile network deployments in rural areas and along highways. 5G on this frequency provides wide coverage outside major cities using fewer base stations.

- 5G 3300 - 3800 MHz. The main frequency range for the deployment of fifth generation mobile communication networks. It provides stable coverage in dense urban areas and a large number of subscribers.

Gain

The signal gain provided by the antenna.

In this case, we mean the gain relative to an perfect isotropic radiator — an antenna that uniformly radiates a radio signal in all directions in the form of spherical waves. Such amplification is carried out by narrowing the flow of radio waves, roughly speaking, by increasing their concentration in space (even omnidirectional antennas emit waves not in the form of a sphere, but in the form of a disk). In this case, the coefficient is measured by the maximum power, which is achieved in the centre of the radiation pattern. Note also that the decibel is used to denote this parameter (more precisely, dBi, decibel relative to the isotrope). This is a non-linear unit: for example, a difference of 3 dB corresponds to a difference of approximately 2 times, 10 dB — 10 times, 20 dB — 100 times, etc. There are tables and calculators that allow you to convert decibels to times.

All this means that the gain is a rather specific parameter, and when choosing its optimal value, consultation with special sources or a professional communications operator may be required. However, this is true primarily for specific situations — for example, installing a 3G antenna in a private house a few kilometers from the base station. The general rule is this: an increase in the gain has a positive effect on the communication range, however, it makes the antenna more susceptible to interference and, usuall...y, affects its dimensions and weight.
Anteniti 4G LTE MIMO 17 dbi often compared