The Best Netgear Orbi Mesh Wi-Fi Systems

Forget about Internet blank spot in your home and office . WiFi Mesh Systems, Faster speeds, greater coverage. WiFi that handles all your connected devices without any slowdowns.

No more dead zones, dropped connections, or buffering. Cover every square inch of your home with smooth, reliable, best-in-class WiFi

Orbi Wi-Fi 6 is a tri-band Wi-Fi System built with the latest and fastest Wi-Fi 6 technology to provide the ultimate smart home experience with Wi-Fi coverage and connection capacity beyond belief.

Keep all Wi-Fi connections strong in every room All the time with enough bandwidth for all your devices Multiple 4K/8K UHD streaming for your Wi-Fi connected speakers. 

Fast online Zoom, Meeting Smart lights Wi-Fi security devices and more Dedicated quad-stream Wi-Fi 6 backhaul allows for streaming 4K or 8K videos without delay Ideal for Gigabit and Multi-Gigabit Internet speed service supporting up to 2 5Gbps download speeds.

Place the satellite anywhere in your home to get Gigabit speeds where you want them.

Easy Setup, Router+Satellite create a mesh network for whole home WiFi coverage without dead spots.

There are two type of WiFi Mesh Solutions from Netgear , Home Solutions and Business Solutions.

For Home Solutions

1. Orbi Tri Band Mesh WiFi 6 Systems, 6 Gbps RBK852, covers 5,000 sq.ft.

NETGEAR Orbi Whole Home Tri-band Mesh WiFi 6 System (RBK852) – 1 Router with 1 Satellite Extender , Get coverage up to 5,000 sq. ft. of coverage and 6Gbps of blazing-fast, consistent WiFi speeds. 

Simultaneously stream, game and video call on 100+ devices in every corner of your home.

2. NETGEAR Orbi Whole Home Tri-band Mesh Wi-Fi 6 System (RBK853) 

The most popular mesh WiFi solution. Cover up to 7,500 sq. ft. with blazing-fast, powerful WiFi with speeds of up to 6Gbps for over 100 devices. Stream, browse, and work uninterrupted throughout your home.

No more dead zones or buffering – just smooth, reliable whole home WiFi.

Router with 2 Satellite Extenders, Coverage Up to 7,500 Square Feet, 100 Devices, AX6000 (Up to 6Gbps)

Omnidirectional Antenna

The Omnidirectional antenna is probably the most common antenna available. Just about every Wi-Fi device you can buy comes with an omni antenna. This is because the omni is so easy to set up, and generally works in consumer environments without much planning . There are few different types of omni antennas. Omni signals spread out sideways , but not vertically.

Top view of coverage an Omni Antenna

An omni antenna sends and receives signals equally in front, behind , to the left , or to the right of the antenna. However, when you go above or below the antenna, signal strength drops off significantly. The trade-off you make when choosing a high-gain antenna is this focusing, or thinning, of the above and below energy. The low-gain omni works better vertically than a high-gain omni, but it won't extend as far horizontally. The omnidirectional antenna sends and receives signals in all directions equally. This is generalization , but it's mostly accurate.

Side view of an omnidirectional antenna signal

Even though an omni antenna does not work very well above and below, it is not considered a directional antenna. Wi-Fi antennas are generally rated in two-dimensional space that assumes it is mounted parallel to the Earth's surface. Knowing how the beam is shaped, and that an antenna is not truly omnidirectional will help you choose the right antenna for your Wi-Fi.

(source : Wi-Fi Toys Extreme Tech)

Building A Classic Paper Clip Antenna

This article will show you how to put together the ultimate homebrew antenna -- a working Yagi antenna for 2.4 GHz Wi-Fi out of litle more than paperclips stuck together. This model is commonly called the Frisko antenna , after the French Frisko brand of ice cream cups whose wooden spoons were used in the first prototypes. 

The current designs of most external Wi-Fi cards put the antenna in a lawed position, with the antenna very close to the computer. This means that the pattern of emissions is often blocked by computer itself. Not only that, the small packaging of wireless cards prevents an optimal design for the internal antenna to pick up wireless network devices more than a couple of 100 feet away.

This is one of the reasons that attaching even a small external antenna can greatly improve signal strength, especially if it is oriented properly.

Dipole Antenna you will build in this article is folded dipole . The Dipole antenna is just the the simplest antenna. The dipole is a half wave antenna that consists of two opposing radiating elements. It's made up of two quarter-wavelength poles that are not connected to each other and fed in the middle by the transmission line. A standard dipole is open on each end, but it can also be folded over on itself.

The Antenna design shows a simple dipole made from steel paperclips . Each arms of the dipole is 31 mm in length, or 1/4 of a wavelength for Wi-i channel 6. The center conductor is soldered to right arm, while the shield is soldered to the left arm. It doesn't matter to which side you solder. 

The dipole antenna is unique in that it can be mounted vertically or horizontally. When standing vertically, the dipole antenna is omnidirectional. When horizontal, this antenna will radiate outward in two directions off the sides (and slightly upwards), like turning a donut on its edge.

(source ; Wi-Fi Toy Extreme Tech)

Build DIY Dual Stacked 300 MHz- 3000 MHz WideBand Yagi TV Antenna, GSM and WIFI Antenna

This Dual Stacked Yagi Antenna can be used for UHF, GSM, WiFi Band from 300 MHz-3000 MHz. The design was done using Yagi Antenna Calculator ANSOF software, you can download  ANSOF trial version for free and also for the paid version, which calculated the length , diameter, and spacing of the materials (elements and boom) used in the construction. 

The Identical Yagi Antennas were stacked (1020 mm center to center spacing) vertically leading to an increase in gain of 15.4 dB when compared with 12.7 dB gain obtainable from a single Yagi antenna and larger capture area (effective aperture).

This research are written by J.llonno, M. Awoji, J.E Onuh from Physics Department, University of Jos, Jos, Nigeria and Physics Department, Kwararafa University, Wukari, Tarabe state, Nigeria

This design was able to solve the problems of underground noise, interference, low picture quality, low gain, and large beamwidth associatedwith a single Yagi antenna. This antenna can be used for VHF,UHF,GSM, Wi-Fi Band  (300–3000 MHz) applications.

Yagi antenna is an example of a resonant directional antenna consisting of driven elements (active components) and parasitic elements (passive components).

An antenna is an arrangement of electrical conductors designed as transceivers of radio waves (Carr, 2001; Volakis, 2007). Antennas convert Radio Frequency (RF) electrical currents into ElectroMagnetic (EM) waves that generate a radiating electromagnetic field.

The driven elements are connected directly to the transmission line (coaxial cable) and receive power from the source. Whereas, the parasitic elements are not connected to the transmission line and receive energy only through mutual induction. Theparasitic elements (directors and reflectors) modify the radiation pattern of the radio waves emitted by the driven element and direct them in a narrow beam in one direction and are arranged parallel to the driven elements. 

The reflector is usually longer than the driven element by 5% and acts as a concave mirror because it reflects the electromagnetic energy incident on it from the driven elements. The director is shorter than the driven element by 5% and acts as a convex mirror as it beams up the incident energy from driven element 

(Milligan, 2005). 

Antenna gain is the measure of the ability of antenna arrays to concentrate the radiated power in a given direction. High-gain antenna radiates energy in a particular direction whereaslow-gain antenna radiates energy in all directions equally. Gain is described using terms suc has antenna gain, power gain, directivity or directive gain. The antenna gain of the Yagi antenna isgreatly dependent on the dipole gain and the number of elements; and is given by (Ochalaand Okeme, 2011): 

 G = 1.66 N     (1) 

 

where 1.66 is the dipole gain and N is the number of elements 

When Yagi antennas are stacked, there is an increase in gain and a decrease in the beam-width. The increased gain is due to the reduction in beam-width. 

There are two types of stacking namely; vertical stacking and horizontal stacking (Blake, 1996; Balanis, 2005, 2008). Stacking two identical antennas on a common vertical mast as seen in Figure 2 significantly narrows the vertical beam-width angle. 

That is, vertically stacked antennas effectively reject those interfering signals arriving from above or below their horizontal plane than that of a single antenna. In this process, gain increases with about 2.5 dB over that of a single antenna (Straw, 2000). 

While stacking two identical Yagi antennas side by side in a horizontal plane significantly narrows the horizontal beam-width angle. That is, the antenna combination “sees” fewer interfering signals arriving from the sides while its vision up and down (in a vertical plane) is virtually unaffected. In this process, gain increases approximately 1.2 dB over that of a single antenna (Straw, 2000). 

The stacking distance can be calculated using Equation 2 (Milligan, 2005). 

 

                       S = 57/BW  (2)  

where S is the stacking distance and BW is the Beam-Width angle 

 

This research work is carried out to solve the problems of underground noise, interference, picture quality, low gain, and large beam-width associated with a single Yagi antenna by stacking two identical Yagi antennas. Vertical stacking was used in the implementation because of the higher gain and greater coverage area. 

Materials and Methods 

 

Materials The materials used are: 

1. Aluminum Boom 

2. Screw nails 

3. Elements  

4. Coaxial cable (75 Ω) 

5. Plastic insulators 

6. Tape  

7. Drilling machine 

8. Hacksaw 

9. Mast or pole for mounting of the antenna 

 

Methods Design of Yagi Antenna An online Yagi antenna calculator (AN-SOF Antenna Simutor) was used for the simulation with design frequency of 889 MHz. The Yagi antenna designed has 8 elements: a reflector, a driven element, and 6 directors with dimensions shown in Table 2 

 

Design Implementation The antenna was constructed using aluminum rods for antenna elements, 2cm-squared metal rodas boom, hacksaw for cutting the materials, gimlet for drilling holes, screw nails for fastening theelements to the boom, measuring tape, welding machine, 75-ohm coaxial cable as transmissionline and feeders to house the terminals of the folded dipoles.

The elements were first measured as stated in Table 2. Holes were drilled at the midpoints of the aluminum rods and boom constructed. A reflectorunit and six directors were cut out. Holes were drilled on them and the directors were screwed into their appropriate positions.

Plastic insulators were used to insulate the directors form the supporting boom.The folded dipole (driven element) was constructed by folding aluminium rod on a bending jig to obtain the folded dipole.A junction box was used to support the folded dipole on the boom. 

Openings were made on the side of the junction box using a drilling machine to allow fitting of the dipole and the coaxial cable. The feeder was fixed to the director boom with screw nails and the terminal of the folded dipole was then fixed to the inside of the feeder. 

With the feeder and folded dipole in place, the reflector and director units were fixed.The relative spacing between elements for optimal reception was determined as follows as shown in Table 3.The antenna was duplicated and were stacked vertically at 1020 mm.  Table below shows Length of rodrequired to produce resonant dipole 

Length to Diameter Ratio (L/D)	Percent Shortening required	Resonant length	Dipole thickness class
5000	2	0.49Lambda	Very thin
50	5	0.475Lambda	Thin
10	9	0.455Lambda	Thick

Approximately one wavelength spacing (at lowest channel frequency) between antennas was maintained. 

Finally, the folded dipoles were connected together by means ofa coaxial cable which serves as the transmission line. Table below shows Simulation Result.

Element	Distance fro driving point of driven element (mm)	Distance expressed as fractions of the wavelength
Reflector	139	0.28
Director 1	55	0.11
Director 2	110	0.23
Director 3	165	0.34
Director 4	275	0.56
Director 5	385	0.8
Director 6	495	1.02

                                

Table below shows Normalised Spacing betwen Elements               

	Relative Spacing
s0,-1	0.29 Lambda
s0,1	0.110 Lambda
s1,2	0,227 Lambda
s2,3	0,227 Lambda
s3,4	0,227 Lambda
s4,5	0,227 Lambda
s5,6	0,227 Lambda

Table below shows Single and Stacked Yagi Results compared

 

The results of this finding have shown that dualstacked Yagi antenna offers high gain compared with single Yagi antenna in operation covering channels in VHF, UHF,GSM, and Wi-Fi bands. This design when properly matched to a feeder cable can solve the problems of underground noise, interference, low picture quality, low gain, 

and large beam-width posed by single Yagi antenna. 

 

Parameters	Single Yagi	Stacked Yagi
Forward Gain	12.720 dB	15.400 dB
Backward Gain	3.415 dB	4.394 dB
Front-Back Ratio	9.306 dB	11.006 dB
Beam-Width	47 degrees	23.5 degrees
Signal Strength	67%	76%
Stacking Distance	-	1020