MONOPOLE ANTENNA

MONOPOLE ANTENNA

A monopole antenna is a type of radio antenna consisting of a straight rod-shaped conductor, placed  perpendicularly over some type of conductive surface, called a ground plane.

 The monopole antenna was invented in 1895 by  Guglielmo Marconi; for this reason it is sometimes called the Marconi antenna. Common types of monopole antenna are the whip, rubber ducky, helical, random wire, umbrella, inverted-L and T-antenna, inverted-F, mast radiator, and ground plane antennas.The monopole antenna is an common antenna that is often used on vehicles and other areas were a large conductive flat area is present (“ground plane”). The standard monopole antenna measures 1/4 wavelength in height (λ/4); however, this antenna must be placed on to a large conductive surface to function properly.

The length of the antenna is determined by the wavelength of the radio waves.  The most common form is the quarter-wave monopole, in which the antenna is approximately one quarter of the wavelength of the radio waves. A monopole antenna has an omnidirectional radiation pattern: it radiates with equal power in all azimuthal directions which means horizontal angle measured clockwise from any fixed reference perpendicular to the antenna

POLE BROADCASTING ANTENNA

While using radio broadcasting, the radio frequency power from the broadcasting transmitter is fed across the base insulator between the tower and a ground system. The ideal ground system for AM broadcasters comprises at least 120 buried copper or phosphor bronze radial wires at least one-quarter wavelength long and a ground-screen. All the ground system components are bonded together, usually by welding, brazing or using coin silver solder to help reduce corrosion. Monopole antennas  uses guy-wires for support which is named as masts in some countries. In the United States, the term “mast” is generally used to describe a pipe supporting a smaller antenna, so both self-supporting and guy-wire supported radio antennas are simply called monopoles if they stand alone. If multiple monopole antennas are used in order to control the direction of radio frequency (RF) propagation, they are called directional antenna arrays.

Yagi-Uda antenna

Yagi-Uda antenna

Yagi-Uda antenna is the most regularly utilized kind of antenna for TV reception, many other domestic and commercial applications. It is an electromagnetic device that collects radio waves.The Yagi-Uda antenna derived its name from its two Japanese inventors Hidetsugu Yagi and Shintaro Uda.

It is mostly known for simple utilization and better execution. Itis highly appreciated for its high gain typically greater than 10 db and directivity. The gain and directivity of the Yagi antenna enables the receiving capacity by improving better degrees of noise ratio to be accomplished, and by reducing interference levels by just getting signals from a provided direction. The frequency of this antenna extends around 30 MHz to 3GHz which is of the VHF and UHF band range and covers about 40 to 60 Km.

Fig: 1 Yagi-Uda antenna

Construction of Yagi-Uda Antenna:

A Yagi-Uda antenna was seen over pretty much every house during the past decades. The parasitic components and the dipole together form a Yagi-Uda antenna. The Yagi antenna design has a dipole as the principle transmitting driven element to which power is applied from a feeder.

The ‘parasitic' components draw power from the driven element and re-radiate it. The stage is in such a way, that it influences the properties of the entire Yagi antenna on the whole, making power be focussed one specific direction and expelling out other directions.

The amplitude and phase of the current that is induced in the parasitic components is decided on their length and the spacing among them and the dipole or driven component. In this event if a component is longer than the resonant length, it gets inductive and shorter, it gets capacitive.

Fig: 2 Components of Yagi-Uda Antenna

There are three kinds of component in a Yagi antenna:

   1. Driven element:

 It is the Yagi antenna component to which power is applied and is a half wave dipole.

   2. Reflector:

 The reflector component is made to be about 5% longer than the driven element and it will have one reflector. It is behind the driven component.

Further reflectors behind the first make no difference to the reception apparatus performance. The reflecting plate gives a slight improvement in execution.

   3.  Director:

These are made to be shorter than the driven element. There might be none, one or more directors in the Yagi reception apparatus. These are put before the driven element, toward the maximum sensitivity. Normally every director will include around 1 dB of gain in the forward direction.

Designing:

For designing this antenna for the given frequency, the following design specifications are should be followed.

Fig: 3 Designing specifications 

Radiation Pattern:

The directional pattern of the Yagi-Uda antenna is highly directive and the radiation patterns are:

Fig: 4 Radiation pattern

The minor lobes are suppressed and the directivity of the major lobe is increased by the addition of directors to the antenna.

The antenna exhibits a directional pattern consisting of a main forward lobe and a number of spurious side lobes. The main one of these is the reverse lobe caused by radiation in the director of the reflector. The antenna can be optimised to either reduce or produce the maximum level of forward gain.

Advantages:

The Yagi antenna offers numerous advantages over different sorts of antenna in numerous applications.

• High gain is achieved.
• High directivity is achieved.
• Ease of handling and maintenance.
• Less amount of power is wasted.
• Broader coverage of frequencies.

Disadvantages:

The negative factors that needed to be taken care while constructions of Yagi antenna are:

•  Long for high gain
•  Prone to noise.
• Prone to atmospheric effects.

Fox Hunt

FOX HUNT:

Transmitter Hunting, or (T-hunting, fox hunting, bunny hunting, and bunny chasing), is a popular way to combine outdoor activity with the amateur radio hobby. The "Fox" hides a hidden transmitter, and the hunters use direction-finding techniques to locate it. To a radio amateur (or “ham”), fox hunting has nothing to do with animals. It is a sport in which individuals race each other to locate a hidden radio transmitter on a known frequency. Since hams are encouraged to design and build their equipment, the typical fox hunt involves a variety of different receivers and antennas with different capabilities. Some of these can display the received signal strength from the hidden transmitter (loosely measuring distance to the transmitter), while others estimate the compass bearing.

Both of these estimates vary in accuracy and precision depending on terrain, environmental conditions, equipment quality, and the skill of the operator. Fox hunting also serves the purpose of preparing radio amateurs for emergency or disaster operations. Because disaster operations require the concerted efforts of multiple radio operators, it seems fitting to explore how the sport changes if fox hunting becomes cooperative.                                                                                   

When participants combine their estimates of distance and bearing, how much faster can they find the transmitter?

Part of the challenge of fox hunting is that measurements are taken infrequently, only once every few minutes. To win the hunt, every minute must count! In the most demanding scenario, each sensor only gets to take one measurement of the fox transmitter. Locating the fox transmitter from a collection of different sensors is a model-based data fusion problem: combining disparate local observations into a global inference. Without a model that describes how signals from the transmitter arrive at each receiver, the signal reports do not help locate the transmitter. Even with such a model, the effects of terrain, the transmitter’s antenna system, and the environment can cause substantial differences between the modelled signal and an actual received signal. Therefore, we must  remain even-handed about assumptions of the quality of the estimates and the quality of the model.

There are several types of transmitter hunts. Transmitter hunting is pursued in several different popular formats. Many transmitter hunts are organized by local radio clubs and may be conducted in conjunction with other events, such as a radio enthusiast convention or club meeting. Before each hunt, participants are informed of the frequency or frequencies on which the transmitters will be operating, and a set of boundaries that define a search area in which the transmitters will be located. Transmitter hunters use radio direction finding techniques to determine the likely direction and distance to the hidden transmitter from several different locations, and then triangulate the probable location of the transmitter. Some hunts may include limits on the amount of time allowed to find a transmitter. Although many transmitter hunts are conducted just for the fun of the activity, some more competitive hunts will recognize winners in publications and offer awards, such as medals or trophies.

Few of the most famous Fox-hunt types are:

1)Mobile transmitter hunts:

Mobile transmitter hunts are organized events where participants travel exclusively or primarily in motor vehicles. Most mobile transmitter hunts use VHF transmitters and receivers.

Some participants use radio direction finding equipment and antennas mounted on a vehicle, whereas others use antennas that are temporarily deployed in an open window or an opening in the vehicle roof that can be easily rotated by hand while the vehicle is in motion. Other participants employ handheld antennas and radios that can only be used when the vehicle is stationary. Some mobile transmitter hunts require participants to leave their vehicles and proceed on foot to reach the actual location of the radio transmitter. The winner of a mobile transmitter hunt can be either the first vehicle to arrive at the hidden transmitter, or the vehicle that travels the shortest overall distance to locate the hidden transmitter. Mobile transmitter hunts are more popular in North America than in other parts of the world.

2)Pedestrian transmitter hunts:

A regulated sport form of transmitter hunting by runners on foot is called Amateur Radio Direction Finding, known worldwide by its acronym, ARDF. It is an amateur sport that combines the skills of orienteering and radio direction finding. ARDF is a timed race in which individual competitors use a topographic map and a magnetic compass to navigate through a diverse, wooded terrain while searching for hidden radio transmitters. ARDF is the most popular form of transmitter hunting outside North America.

3)Fixed location transmitter hunts:

Some transmitter hunts feature a "mail-in" competition, in which teams in fixed locations work together to locate hidden transmitters, then secretly give the coordinates to the organizers without actually traveling to the transmitter location. The team which provides the closest coordinates wins, thus a team which believes that the transmitter is in the northwest parking lot at 2nd and Elm (if it is there) will beat a team which says that the location is 2nd and Elm. This type of hunt enables participation by contestants who are unable to travel, such as shut-ins, school groups, etc., and requires a greater level of skill and coordination.

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