Sattellite antennas are curved because they will get a better signal or the television would be buffering
Satellite antennas are typically curved to allow them to receive signals from a wider range of directions. This is due to the fact that the curved surface increases the gain of the antenna allowing it to better receive signals from any direction. Curved antennas also help reduce the amount of noise that is picked up resulting in a clearer signal. Additionally curved antennas often have a larger reception area than straight antennas which allows them to pick up a wider range of frequencies. There are a few different types of curved antennas that are used for satellite communications. The most common type is the parabolic antenna which is made up of a parabolic reflector and a feed horn. This type of antenna is highly directional meaning that it can focus on one particular satellite in the sky. Other types of curved antennas include Yagi antennas which can receive signals from a number of different directions and helical antennas which are used for receiving signals from a single satellite. The use of curved antennas in satellite communication systems has numerous advantages. They allow for a wider range of frequencies to be received resulting in a clearer signal. They also reduce noise resulting in a clearer signal. Lastly curved antennas are often more efficient than straight antennas meaning that they can pick up signals from further away.
the orbit
A satellite is a body in orbit around another lager body. A probe is a machine sent to a specific place or specific course in space. Comment: That doesn't seem to answer the question. The curved path that a satellite follows is either a circle or an ellipse
The gravitational pull is causing the satellite to orbit around because the pull is the same all the way around. If it ever managed to leave the gravitational pull, it would just wander pretty aimlessly and even then it would go in a straight line. Hope this helps! Comment: In more "scientific" words : 1. The satellite has a velocity that is along the line of its orbit ( in other words "tangential" to the orbit, at any instant). 2. The planet, that the satellite orbits, is trying to pull the satellite in the direction of the planet. 3. The combination of these things results in the curved path. The satellite is constantly being diverted from its direction at a tangent to the orbit by gravity.
It orbits the Earth.However, even communications satellites in geosynchronous orbits are in orbit around the Earth; it's just that each orbit takes exactly one day, and so the satellite appears to be stationary above a point on the Earth. We can use this fact to our advantage; instead of building tracking antennas that follow a rapidly moving object, a tracking antenna for a geosynchronous satellite never needs to be turned.Which is a good thing, because those little "Dish" and DirecTV antennas can't be easily turned!
Satellite antennas are typically curved to allow them to receive signals from a wider range of directions. This is due to the fact that the curved surface increases the gain of the antenna allowing it to better receive signals from any direction. Curved antennas also help reduce the amount of noise that is picked up resulting in a clearer signal. Additionally curved antennas often have a larger reception area than straight antennas which allows them to pick up a wider range of frequencies. There are a few different types of curved antennas that are used for satellite communications. The most common type is the parabolic antenna which is made up of a parabolic reflector and a feed horn. This type of antenna is highly directional meaning that it can focus on one particular satellite in the sky. Other types of curved antennas include Yagi antennas which can receive signals from a number of different directions and helical antennas which are used for receiving signals from a single satellite. The use of curved antennas in satellite communication systems has numerous advantages. They allow for a wider range of frequencies to be received resulting in a clearer signal. They also reduce noise resulting in a clearer signal. Lastly curved antennas are often more efficient than straight antennas meaning that they can pick up signals from further away.
The options for car radio antennas include internal car antennas, external car antennas, power antennas, and satellite antennas. The internal antenna is the least effective and most cars come with either the external fixed antenna or the power antenna unless their is a satellite radio in the car and then it is a satellite antenna.
the orbit
They do not make very good antennas though.
Light weighted antennas are used for communication
No they cannot. Snails use their antennas to see and smell.
Zois Papadopoulos has written: 'Patch antennas for mobile satellite handhelds'
The digital TV antennas were made when the analog satellites for TVs went to a Digital satellite. With a converter box and the digital antennas it still makes it possible to use TV that still use the old rabbit ears.
Xiaodong Chen has written: 'Antennas for global navigation satellite systems' -- subject(s): Global Positioning System, Space vehicles, Antennas (Electronics), Mobile communication systems, Radio antennas, Radio wave propagation
The reflector piece of a Dish satellite is curved in order to receive the proper signals from the orbiting satellites in space (also known as orbital locations). In order to view a specific satellite channel, each Dish reflector is designed with a different curvature.
Satellite terminals with fixed antennas, such as the TV dish on the garage or the corner of the house.
R. Acosta has written: 'System overview on electromagnetic compensation for reflector antenna surface distortion' -- subject(s): Antennas, Reflector, Phased array antennas, Reflector Antennas 'ACTS on-orbit multibeam antenna pattern measurements' -- subject(s): ACTS, Antenna radiation patters, Cassegrain antennas, Electromagnetic measurement, Extremely high frequencies, Microwave antennas, Multibeam antennas, Satellite antennas 'Active feed array compensation for reflector antenna surface distortions' -- subject(s): Antenna arrays 'Analytical approximation of a distortred reflector surface defined by a discrete set of points' -- subject(s): Antennas, Reflector, Artificial satellites in telecommunication, Reflector Antennas 'Computation of the radiation characteristics of a generalized phased array' -- subject(s): Numerical analysis, Near fields, Phased arrays, Microwave circuits, Phased array antennas, Antenna radiation patterns, Satellite antennas, Integrated circuits, Microwave integrated circuits